Prevalence of musculoskeletal pain in adolescents and association with computer and videogame use

Silva, Georgia Rodrigues Reis; Pitangui, Ana Carolina Rodarti; Xavier, Michele Katherine Andrade; Correia-Júnior, Marco Aurélio Valois; Araújo, Rodrigo Cappato De

doi:10.1016/j.jped.2015.06.006

Abstract

Objective:

This study investigated the presence of musculoskeletal symptoms in high school adolescents from public schools and its association with electronic device use.

Methods:

The sample consisted of 961 boys and girls aged 14–19 years who answered a questionnaire regarding the use of computers and electronic games, and questions about pain symptoms and physical activity. Furthermore, anthropometric assessments of all volunteers were performed. The chi-squared test and a multiple logistic regression model were used for the inferential analysis.

Results:

The presence of musculoskeletal pain symptoms was reported by 65.1% of the adolescents, being more prevalent in the thoracolumbar spine (46.9%), followed by pain in the upper limbs, representing 20% of complaints. The mean time of use for computers and electronic games was 1.720 and 583 minutes per week, respectively. The excessive use of electronic devices was demonstrated to be a risk factor for cervical and lumbar pain. Female gender was associated with the presence of pain in different body parts. Presence of a paid job was associated with cervical pain.

Conclusion:

A high prevalence of musculoskeletal pain in adolescents, as well as an increased amount of time using digital devices was observed. However, it was only possible to observe an association between the increased use of these devices and the presence of cervical and low back pain.

Keywords
Musculoskeletal pain; Adolescent; Computer systems; Video games

Resumo

Objetivo:

Investigar a presença de sintomas musculoesqueléticos em adolescentes estudantes do ensino médio em escolas públicas e sua associação com o uso de dispositivos eletrônicos.

Método:

A amostra foi composta por 961 meninos e meninas entre 14 e 19 anos que responderam questionário sobre o uso de computadores, jogos eletrônicos e questões relacionadas a sintomas dolorosos e atividade física. Além disso, todos os voluntários foram submetidos à avaliação antropométrica. Para análise inferencial foram usados os testes de qui-quadrado e modelo múltiplo de regressão logística.

Resultados:

A presença de sintomas de dor musculoesquelética foi reportada por 65,1% dos adolescentes, mais prevalente na coluna toracolombar (46,9%), seguida por dor nos membros superiores (20%). O tempo médio de uso de computador e jogos eletrônicos foi de 1.720 e 583 minutos por semana, respectivamente. O uso excessivo dos dispositivos eletrônicos mostrou-se como fator de risco para dor cervical e lombar. O sexo feminino apresentou associação com a presença de dor em diferentes partes do corpo. A atividade profissional esteve associada com a dor cervical.

Conclusão:

Observou-se alta prevalência de dor musculoesquelética nos adolescentes e elevado tempo de uso dos dispositivos eletrônicos. Entretanto, foi possível observar somente a associação do uso excessivo desses dispositivos e a presença de dor cervical e lombar.

Palavras-chave
Dor musculoesquelética; Adolescente; Sistemas de computação; Jogos de vídeo

Introduction

The use of electronic devices has, in recent years, become an important part in the lives of adolescents, who regularly use computers to carry out academic and leisure activities.¹1 Milde-Busch A, Von Kries R, Thomas S, Heinrich S, Straube A, Radon K. The association between use of electronic media and prevalence of headache in adolescents: results from a population-based cross-sectional study. BMC Neurol. 2010;10:12.^,²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41. Other resources used by this population include the different types of electronic games, which, just like computers, have attracted an exaggerated interest, causing children and adolescents to spend hours being entertained by such technologies, often interfering with their social relationships.³3 Desai RA, Krishnan-Sarin S, Cavallo D, Potenza MN. Video--gaming among high school students: health correlates, gender differences, and problematic gaming. Pediatrics. 2010;126:e1414-24.^,⁴4 Gentile D. Pathological video-game use among youth ages 8 to 18. Psychol Sci. 2009;20:594-602.

The excessive use of these devices has been associated with several health problems, such as obesity, headaches, anxiety, stress, sleep disorders, musculoskeletal pain, and decreased physical activity levels.¹1 Milde-Busch A, Von Kries R, Thomas S, Heinrich S, Straube A, Radon K. The association between use of electronic media and prevalence of headache in adolescents: results from a population-based cross-sectional study. BMC Neurol. 2010;10:12.^,²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,⁵5 Dumith SC, Hallal PC, Menezes AM, Araújo CL. Seden-tary behavior in adolescents: the 11-year follow-up of the 1993 Pelotas (Brazil) birth cohort study. Cad Saude Publica. 2010;26:1928-36.^,⁶6 Dumith SC, Domingues MR, Gigante DP, Hallal PC, Menezes AM, Kohl HW. Prevalence and correlates of physical activity among adolescents from Southern Brazil. Rev Saúde Pública. 2010;44:457-67.

Musculoskeletal symptoms are a major cause of acute, chronic, and recurrent pain in children and adolescents, significantly affecting the psychosocial status and considered a public health problem.⁷7 Roth-Isiqkeit A, Thyen U, Stoven H, Schwarzberger J, Schmuc-ker P. Pain among children and adolescents: restrictions in daily living and triggering factors. Pediatrics. 2005;115:e152-62.^–¹¹11 Janini SN, Dória-Filho U, Damiani D, Silva CA. Musculoskeletal pain in obese adolescents. J Pediat (Rio J). 2011;87:329-35. Their prevalence in recent studies with adolescents has ranged between 19.5% and 56%.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,⁸8 Shan Z, Deng G, Li J, Li Y.Zhang Y, Zhao Q. Correlational analy-sis of neck/shoulder pain and low back pain with the use of digital products, physical activity and psychological status among adolescents in Shanghai. PLOS ONE. 2013;8:e78109.^–¹¹11 Janini SN, Dória-Filho U, Damiani D, Silva CA. Musculoskeletal pain in obese adolescents. J Pediat (Rio J). 2011;87:329-35.

Studies have shown that prolonged periods in a static position may result in spinal column pain and increase the risk of developing complaints in other body partss.¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14.^–¹⁵15 Kelly G, Dockrel S, Galvin R. Computer use at school: its effect on posture in discomfort in schoolchildren. Work. 2009;32:321-8. A study carried out with Finnish adolescents suggested that musculoskeletal symptoms that cause moderate to severe pain are common among computer users.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.

The association between computer use and the presence of musculoskeletal pain in adolescents was not demonstrated in a study conducted in Brazil in 2004.¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14. However, studies performed in developed countries have demonstrated an association between time of computer use and painful symptoms in the lower limbs and cervical spinal column of adolescents.¹³13 Smith L, Louw Q, Crous L, Grimmer-Somers K. Prevalence of neck pain and headaches: impact of computer use and other associative factors. Cephalalgia. 2009;29:250-7.^,¹⁶16 Bostrom M, Dellve L, Thomée S, Hagberg M. Risk factors for generally reduced productivity - a prospective cohort study of young adults with neck or upper-extremity musculoskeletal symptoms. Scand J Work Environ Health. 2008;34:120-32.^,¹⁷17 Jacobs K, Hudak S, McGiffert J. Computer-related posture and musculoskeletal discomfort in middle school students. Work. 2009;32:275-83. Therefore, it can be observed that the time factor, added to the technological development and socioeconomic level of a region, may have influenced these results.

Considering the recent technological and economic growth observed in Brazil and that concomitant to this fact, there has been an increase in access to these technologies, it is believed that today's adolescents are more exposed to these resources. Additionally, in 2012, the State Secretariat of Education (Secretaria Estadual de Educação – SEE) of Pernambuco, using a strategy considered to be innovative, distributed laptops to all high school students, thereby increasing access to this type of technology. The aim of this study was to determine the prevalence of musculoskeletal pain in adolescents and its association with the use of electronic devices.

Methods

This was an epidemiological, correlational, and cross-sectional study, which was approved by the Research Ethics Committee of the Universidade de Pernambuco under protocol No. CAAE 13598313.5.0000.5207.

The study population consisted of adolescents aged 14–19, enrolled in public high schools in the city of Recife, state of Pernambuco, Brazil. According to data provided by the SEE, in 2012 an estimated 55,058 adolescents were enrolled in 108 public high schools. The following criteria were used to quantify sample size: estimated population of 55,058 students; 95% confidence interval; sampling error of five percentage points; estimated prevalence of 50%; sample loss of 20% and a two-fold design effect.

The sample selection procedure followed a sequence of steps aiming to obtain a representative sample regarding the distribution of students according to geographic region and school size. Initially, the number of schools that had high school classes was observed. Then, taking into account the geographical and organizational distribution, schools were divided into each of the Regional Education Offices. Finally, schools were divided into three categories: small (up to 200 students), medium-sized (201–499 students), and large (500 or more students).¹⁸18 Tenório MC, Barros MV, Tassitano RM, Bezerra J, Tenório JM, Hallal PC. Physical activity and sedentary behavior among ado-lescent high school students. Rev Bras Epidemiol. 2010;13: 105-17.^,¹⁹19 Carvalho PD, Barros MV, Lima RA, Santos CM, Mélo EN. Health risk behaviors and psychosocial distress indicators in high school students. Cad Saude Publica. 2011;27:2095-105.

In the second stage, the cluster sampling was performed in two steps, considering the school and the class as sampling units. In the first step, school proportionality was considered by size; in the second step, the proportionality of classes was considered.¹⁹19 Carvalho PD, Barros MV, Lima RA, Santos CM, Mélo EN. Health risk behaviors and psychosocial distress indicators in high school students. Cad Saude Publica. 2011;27:2095-105. Therefore, the authors found a minimum number of 23 schools and 96 classes, which represent 20% of public schools in Recife and a total of 954 adolescents.

Inclusion criteria included attending one of the selected schools and age between 14 and 19 years. Exclusion criteria comprised the inadequate completion of the questionnaire or refusal to undergo anthropometric measurements. Pregnant women and students who had musculoskeletal pain or injuries due to infectious, genetic, or traumatic disorders were excluded from the study.

Data were collected through a constructed and adapted questionnaire aimed to assess sociodemographic variables (age, gender, school year, presence of a paid job, and family income), data on the use of computer and video games (age of onset of use, weekly frequency, and time of use), presence of musculoskeletal pain (location and use of pain medications), and physical activity level.

A self-administered questionnaire was used to evaluate the use of electronic devices and painful symptoms, which included aspects of the musculoskeletal system painful symptoms, body diagram for symptom location, and questions related to the use of computer and video games. This tool has excellent interday reliability (Kappa > 0.72).¹¹11 Janini SN, Dória-Filho U, Damiani D, Silva CA. Musculoskeletal pain in obese adolescents. J Pediat (Rio J). 2011;87:329-35.^,¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14.

To evaluate the pain symptoms, the adolescents were asked to indicate in the body chart the regions where they had experienced pain in the last six months. As for the pain symptoms, the adolescents answered the questions related to the use of electronic devices, always considering the six months prior to the day of data collection. Time periods greater than 4 h/day for the use of all electronic equipment, 3 h/day for computers, and 1 h/day for video games were considered excessive. These cutoff points were determined by the median value found in the assessed sample.

The level of physical activity was assessed based on the answers to the International Physical Activity Questionnaire (IPAQ) – Short Form,²⁰20 Craig CL, Marshall AL, Sjostrom M, Bauman AE, Booth ML, Ainsworth BE, et al. International Physical Activity Questionnaire: 12-country reliability and validity. Med Sci Sports Exerc. 2003;35:1381-95. and volunteers were classified as active or insufficiently active. The anthropometric data were recorded using a G-THEC portable electronic scale with 150 kg capacity (Camry Electronic, USA) and a WCS portable stadiometer (Cardiomed Comércio de Equipamentos Médicos LTDA, Brazil). These data were used to calculate body mass index (BMI) and to perform overweight and obesity classification.²¹21 Cole TJ, Bellizzi MC, Flegal KM, Dietz WH. Establishing a standard definition for child overweight and obesity worldwide: international survey. BMJ. 2000;320:1240-3.

Data analysis was performed using SPSS software (IBM Corp. Released 2011. IBM SPSS Statistics for Windows, Version 20.0; USA). Bivariate logistic regression models were constructed to test the isolated association between the dependent variable and each independent variable, as well as to analyze the variables in the model, to explore the possible confounding factors and identify the need for statistical adjustment of analysis. Multiple logistic regression was used through the estimate of odds ratio and 95% confidence intervals (95% CI) to express the degree of association between the independent variables and the presence of pain.

For the final multiple model, the selected variables were those whose p-value was <0.20. In all tests, a p-value <0.05 was considered statistically significant. Considering the sampling design used in the study (cluster sampling in two stages), it was decided to perform inferential statistics using the "complex sampling mode" of SPSS to apply the correction of estimates for the design effect.

Results

In total, 1020 adolescents were included in the study. However, 59 individuals were excluded due to errors when completing the questionnaire. The final sample consisted of 961 adolescents. The sociodemographic and anthropometric characteristics, nutritional status, physical activity level, presence of a paid job, and data related to the use of electronic devices are described in Table 1.

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Table 1
Sociodemographic, anthropometric characteristics, nutritional status, physical activity level, and occupation of adolescents from public schools in Recife, stratified by gender.

The presence of pain symptoms was reported by 626 (65.1%) adolescents. The anatomical region with the highest prevalence of pain complaints was the thoracolumbar spine (n = 451; 46.9% [95% CI: 43.7–50.1%]), followed by the upper limbs (n = 192; 20% [95% CI: 17.5–22.7%]), cervical spine (n = 178; 18.5% [95% CI: 16.1–21.1%]), and scapular region (n = 152; 15.8% [95% CI: 13.5–18.3%]).

It was observed that 199 adolescents (31.8% [95% CI: 28.2–35.6%]) reported that using the computer was the triggering factor for at least one symptom. Other factors cited as triggers were physical exercise in 128 (20.5% [95% CI: 17.6–23.8%]) and the use of electronic games in 18 adolescents (2.9% [95% CI: 1.7–4.5%]).

Another assessed aspect was the influence of pain symptoms when performing activities of daily living, with the adolescents reporting that at least one of the pain symptoms interfered with or hindered the accomplishment of study tasks (143; 22.8% [95% CI: 19.7–26.3%]), sleeping (115; 18.4% [95% CI: 15.4%–21.6%]), and playing sports (110; 17.6% [95% CI: 14.7–20.8%]). Additionally, 186 (29.7% [95% CI: 26.2–33.5%]) adolescents said that the presence of pain made them more nervous. Finally, 201 (32.1% [95% CI: 28.5–35.9%]) adolescents reported that they made sporadic use of analgesics, while another 70 (11.1% [95% CI: 8.8–13.9%]) reported that they frequently used these drugs.

The results of the bivariate regression analysis showed that female gender was associated with musculoskeletal pain in all assessed anatomical regions. An association was observed between the presence of cervical pain and having a paid job as well as high amount of time using electronic devices (Table 2). High amount of time using electronic devices was associated with pain symptoms in the thoracolumbar region and excess weight was associated with pain symptoms in the upper limbs (Table 3).

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Table 2
Sociodemographic variables, physical activity level, nutritional status, and use of electronic devices and their association with complaints of pain in the cervical and scapular regions.

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Table 3
Sociodemographic variables, level of physical activity, nutritional status, and use of electronic devices and their association with complaints of pain in the thoracolumbar region and upper limbs.

The multivariate model results for the pain symptoms in the four assessed areas are shown in Table 4. The variable gender remained associated in the final model of the four assessed areas. The total time of electronic device use remained associated with pain in the cervical and thoracolumbar regions. Presence of a paid job remained associated with the presence of pain in the cervical region and the nutritional status remained in the final model of upper limb pain, although without a significant association.

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Table 4
Multiple association model of musculoskeletal pain in high school adolescents.

Discussion

A high prevalence of musculoskeletal pain was observed among the adolescents, higher than that shown in previous studies in Brazil¹¹11 Janini SN, Dória-Filho U, Damiani D, Silva CA. Musculoskeletal pain in obese adolescents. J Pediat (Rio J). 2011;87:329-35.^,¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14. and in other countries.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,²²22 Torsheim T, Eriksson L, Schnohr CW, Hansen F, Bjarnason T, Vali-maa R. Screen-based activities and physical complaints among adolescents from the Nordic countries. BMC Public Health. 2010;10:324. This evidence alone reinforces the importance of such investigation of factors associated with this problem and thus, it becomes essential to provide health assessment and comprehensive health care.

As for symptom location, the region with the highest prevalence of pain complaints was the thoracolumbar spine (46.9%). Recent studies with Brazilian²³23 Lemos AT, Santos FR, Moreira RB, Machado DT, Braga FC, Gaya AC. Low back pain and associated factors in children and adoles-cents in a private school in Southern Brazil. Cad Saude Publica. 2013;29:2177-85. and Chinese students⁸8 Shan Z, Deng G, Li J, Li Y.Zhang Y, Zhao Q. Correlational analy-sis of neck/shoulder pain and low back pain with the use of digital products, physical activity and psychological status among adolescents in Shanghai. PLOS ONE. 2013;8:e78109. showed a prevalence rate close to 32% for low back pain. Although these findings were lower, they still seem to corroborate the present results, as this study also included symptoms related to the thoracic spine, which may explain this difference. The second most prevalent pain was in the upper limbs, followed by the cervical spine. These findings corroborate previous studies,²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,³3 Desai RA, Krishnan-Sarin S, Cavallo D, Potenza MN. Video--gaming among high school students: health correlates, gender differences, and problematic gaming. Pediatrics. 2010;126:e1414-24. which reported prevalence of pain in the cervical and shoulder regions in approximately 21–22% of adolescents.

Regarding the use of electronic devices, several studies have shown increased computer use, as demonstrated in this study, with prevalence ranging between 74% and 99% of adolescents.¹1 Milde-Busch A, Von Kries R, Thomas S, Heinrich S, Straube A, Radon K. The association between use of electronic media and prevalence of headache in adolescents: results from a population-based cross-sectional study. BMC Neurol. 2010;10:12.^,¹¹11 Janini SN, Dória-Filho U, Damiani D, Silva CA. Musculoskeletal pain in obese adolescents. J Pediat (Rio J). 2011;87:329-35.^,¹⁴14 De Vitta A, Martinez MG, Piza NT, Simeão SF, Ferreira NP. Pre-valence of lower back pain and associated factors in students. Cad Saude Publica. 2011;27:1520-8. This result may be associated with the implemented government program, which distributed the equipment to all high school students and contributed to increasing access to this technology, which was previously only associated with families of higher socioeconomic level.⁴4 Gentile D. Pathological video-game use among youth ages 8 to 18. Psychol Sci. 2009;20:594-602.^,⁵5 Dumith SC, Hallal PC, Menezes AM, Araújo CL. Seden-tary behavior in adolescents: the 11-year follow-up of the 1993 Pelotas (Brazil) birth cohort study. Cad Saude Publica. 2010;26:1928-36.^,²⁴24 Silva KS, Nahas MV, Hoefelmann LP, Lopes AS, Oliveira ES. Associations between physical activity, body mass index, and sedentary behaviors in adolescents. Rev Bras Epidemiol. 2008;11:159-68. According to previous studies, the total weekly time spent by adolescents using computers ranged from 80 to 840 min.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,⁴4 Gentile D. Pathological video-game use among youth ages 8 to 18. Psychol Sci. 2009;20:594-602.^,⁵5 Dumith SC, Hallal PC, Menezes AM, Araújo CL. Seden-tary behavior in adolescents: the 11-year follow-up of the 1993 Pelotas (Brazil) birth cohort study. Cad Saude Publica. 2010;26:1928-36.^,²⁴24 Silva KS, Nahas MV, Hoefelmann LP, Lopes AS, Oliveira ES. Associations between physical activity, body mass index, and sedentary behaviors in adolescents. Rev Bras Epidemiol. 2008;11:159-68.^–²⁷27 Strasburger VC, Jordan AB, Donnerstein E. Health effects of media on children and adolescents. Pediatrics. 2010;125:756-67. Nonetheless, the present study showed time spent at the computer close to 1720 minutes per week, raising questions about that time, as several studies have emphasized the association of several health complaints with excessive use of such devices.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,²⁸28 Primack BA, Carroll MV, McNamara M, Klem ML, King B, Rich M, et al. Role of video games in improving health-related outcomes: a systematic review. Am J Prev Med. 2012;42:630-8.

Regarding the use of electronic games, Milde-Busch et al.¹1 Milde-Busch A, Von Kries R, Thomas S, Heinrich S, Straube A, Radon K. The association between use of electronic media and prevalence of headache in adolescents: results from a population-based cross-sectional study. BMC Neurol. 2010;10:12. reported a low frequency (27%) among adolescents, which differs from the results of this study. This higher frequency is probably due to the fact that electronic games have become increasingly popular, representing one of the most important leisure activities for adolescents, regardless of age and socioeconomic strata.²⁵25 Burke A, Peper E. Cumulative trauma disorder risk for chil-dren using computer products: results of a pilot investigation with a student convenience sample. Public Health Rep. 2002;117:350-7.^,²⁶26 Altenburg TM, Singh AS, van Mechelen W, Brug J, Chinapaw MJ. Direction of the association between body fatness and self--reported screen time in Dutch adolescents. Int J Behav Nutr Phys Act. 2012;24(9):4. This finding is reinforced by the data found in relation to the weekly time of use, which averaged close to 583 min, higher than the 390 min described in previous studies.⁴4 Gentile D. Pathological video-game use among youth ages 8 to 18. Psychol Sci. 2009;20:594-602.^,⁵5 Dumith SC, Hallal PC, Menezes AM, Araújo CL. Seden-tary behavior in adolescents: the 11-year follow-up of the 1993 Pelotas (Brazil) birth cohort study. Cad Saude Publica. 2010;26:1928-36.^,¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14.

Regarding the analysis of factors associated with pain complaints, it was observed that the female gender, total time of electronic device use, nutritional status, and presence of a paid job remained in the final statistical models.

Female gender was associated with pain complaints in all anatomical regions and was considered a risk factor. The presence of pain complaints in different body regions by the adolescents was also demonstrated in a study carried out in Finland, in which girls reported pain in all anatomical sites and, consequently, more disruption to daily life.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.

The gender question can be explained by the fact that women complain more than men, often reporting more relevant health information due to social and educational issues, as well as the presence of hormonal changes during puberty.⁹9 Yac W, Luo C, Ai F, Chen Q. Risk factors for nonspecific low--back pain in Chinese adolescents a case -control study. Pain Med. 2012;13:658-64. These findings have been demonstrated by other studies in the literature.¹⁶16 Bostrom M, Dellve L, Thomée S, Hagberg M. Risk factors for generally reduced productivity - a prospective cohort study of young adults with neck or upper-extremity musculoskeletal symptoms. Scand J Work Environ Health. 2008;34:120-32.^,²³23 Lemos AT, Santos FR, Moreira RB, Machado DT, Braga FC, Gaya AC. Low back pain and associated factors in children and adoles-cents in a private school in Southern Brazil. Cad Saude Publica. 2013;29:2177-85. Costigan et al.²⁹29 Costigan SA, Barnett L, Plotnikoff RC, Lubans DR. The health indicators associated with screen-based sedentary behavior among adolescent girls: a systematic review. J Adolesc Health. 2013;52:382-92. reported that girls show lower levels of physical activity and increased time spent in sedentary behaviors associated with hormonal variations, which negatively contribute to several health indicators, including musculoskeletal pain.

Another sociodemographic factor associated with pain symptoms, specifically cervical pain, was presence of a paid job. Although studies conducted with adolescents about pain symptoms have similar characteristics to those of the present study, regarding the assessment of schoolchildren²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,¹⁴14 De Vitta A, Martinez MG, Piza NT, Simeão SF, Ferreira NP. Pre-valence of lower back pain and associated factors in students. Cad Saude Publica. 2011;27:1520-8.^,²²22 Torsheim T, Eriksson L, Schnohr CW, Hansen F, Bjarnason T, Vali-maa R. Screen-based activities and physical complaints among adolescents from the Nordic countries. BMC Public Health. 2010;10:324.^,²³23 Lemos AT, Santos FR, Moreira RB, Machado DT, Braga FC, Gaya AC. Low back pain and associated factors in children and adoles-cents in a private school in Southern Brazil. Cad Saude Publica. 2013;29:2177-85. and the prevalence of adolescent females,²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,¹⁶16 Bostrom M, Dellve L, Thomée S, Hagberg M. Risk factors for generally reduced productivity - a prospective cohort study of young adults with neck or upper-extremity musculoskeletal symptoms. Scand J Work Environ Health. 2008;34:120-32. many of these studies²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,²²22 Torsheim T, Eriksson L, Schnohr CW, Hansen F, Bjarnason T, Vali-maa R. Screen-based activities and physical complaints among adolescents from the Nordic countries. BMC Public Health. 2010;10:324.^,²³23 Lemos AT, Santos FR, Moreira RB, Machado DT, Braga FC, Gaya AC. Low back pain and associated factors in children and adoles-cents in a private school in Southern Brazil. Cad Saude Publica. 2013;29:2177-85. disregarded data related to having a paid job and employment. Zapata et al.¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14. reported that less than 1% of the assessed adolescents had a job.

In the present study, approximately 18% of the adolescents reported having a job, differing from the results found in the literature.¹³13 Smith L, Louw Q, Crous L, Grimmer-Somers K. Prevalence of neck pain and headaches: impact of computer use and other associative factors. Cephalalgia. 2009;29:250-7. This finding can be explained by differences in socioeconomic status of the assessed samples, as previous studies²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14.^,¹⁴14 De Vitta A, Martinez MG, Piza NT, Simeão SF, Ferreira NP. Pre-valence of lower back pain and associated factors in students. Cad Saude Publica. 2011;27:1520-8.^,²²22 Torsheim T, Eriksson L, Schnohr CW, Hansen F, Bjarnason T, Vali-maa R. Screen-based activities and physical complaints among adolescents from the Nordic countries. BMC Public Health. 2010;10:324.^,²³23 Lemos AT, Santos FR, Moreira RB, Machado DT, Braga FC, Gaya AC. Low back pain and associated factors in children and adoles-cents in a private school in Southern Brazil. Cad Saude Publica. 2013;29:2177-85. reported assessing middle-class adolescents or students from private schools, whereas in this study the majority of assessed students had low family income. Possibly due to this situation, this sample had to work to help with family expenses, which can contribute to greater physical and mental stress.

The use of electronic devices was only associated with pain complaints in the spinal column. In this respect, it was observed that the isolated use of computers or electronic games showed no association with pain complaints; however, when assessing the combined use of these devices, it became clear that the elevated total time of use is characterized as a risk factor for the presence of cervical and thoracolumbar pain.

Corroborating these results, Hakala et al.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41. also found that computer use is associated with cervical pain; however, with a mean time of use of 2 h daily. Another study showed that the longer the time of screen exposure, the greater the chances of developing spinal column pain.²²22 Torsheim T, Eriksson L, Schnohr CW, Hansen F, Bjarnason T, Vali-maa R. Screen-based activities and physical complaints among adolescents from the Nordic countries. BMC Public Health. 2010;10:324. Zapata et al.¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14. found no association between pain and the use of electronic games and computers, differing from the results found in this study. This difference is possibly due to the characteristics related to the time of the study, given that the access and screen time reported by Zapata et al.,¹²12 Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14. ten years ago, was lower than that found in the present study and in others.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.^,²²22 Torsheim T, Eriksson L, Schnohr CW, Hansen F, Bjarnason T, Vali-maa R. Screen-based activities and physical complaints among adolescents from the Nordic countries. BMC Public Health. 2010;10:324.

In addition to the presence of pain and its location, the assessment of its intensity is also recommended. However, the study by Hakala et al.²2 Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41. is the only one that assessed the association between computer use and the location and intensity of pain symptoms in the spinal column of adolescents. Although the authors reported that excessive use of these devices is related to moderate and severe intensity, they point out that these data should be analyzed with caution, considering that the study cross-sectional design does not allow for inference of causality, as well as the fact that a self-report evaluation may show recall bias. The authors also showed that the subjective nature of pain assessment can generate incorrect information and/or overestimation of the responses. Corroborating this information, Rothaug et al.³⁰30 Rothaug J, Weiss T Meissner W. How simple can it get? Mea-suring pain with NRS items or binary items. Clin J Pain. 2013;29:224-32. described that pain assessment with binary responses is a more practical method for pain assessment when compared to the use of numerical scales, with the binary method being preferred by most patients.

Considering this information, it was decided not to use pain intensity assessment in this study, as all these possible limitations, in addition to the six-month recall, could generate a significant bias, thus affecting the results. The authors considered the possibility that, in six months, the adolescents could have had more than one episode of pain, and these episodes could have had variations in their duration; therefore, the report of pain intensity would be complex, subjective, and subject to considerable variation.

Although no association was verified between the use of electronic devices and other pain complaints, it was observed that 31.8% of the adolescents reported that using a computer was a triggering factor of at least one symptom. Another important aspect refers to the report that the presence of pain symptoms interfered with many daily activities, such as performing tasks, sleep, and practicing sports, as well as being responsible for self-medication in a significant number of subjects, which can cause health problems or even mask symptoms of more important diseases.

This study has some sample-related limitations, as these were public school students and, therefore its generalization to other populations is not possible. The data were obtained from students' self-reports and, thus, recall bias may be possible; it is important to exercise caution when interpreting these data. However, these results are relevant, as they suggest that technological development, which society is facing, can have significant effects, requiring constant monitoring of health indicators and associated factors.

Finally, the results showed a high prevalence of musculoskeletal pain and the high amount of time spent using electronic devices. However, the increased use of these devices only showed an association with pain in the cervical and thoracolumbar regions.

☆
Please cite this article as: Silva GR, Pitangui AC, Xavier MK, Correia-Júnior MA, Araújo RC. Prevalence of musculoskeletal pain in adolescents and association with computer and videogame use. J Pediatr (Rio J). 2016;92:188-96.

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Hakala PT, Saarni LA, Punamaki RL, Wallenius MA, Nygârd CH, Rimpela AH. Musculoskeletal symptoms and computer use among Finnish adolescents - pain intensity and inconvenience to everyday life: a cross-sectional study. BMC Musculoskelet Disord. 2012;13:41.
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Dumith SC, Domingues MR, Gigante DP, Hallal PC, Menezes AM, Kohl HW. Prevalence and correlates of physical activity among adolescents from Southern Brazil. Rev Saúde Pública. 2010;44:457-67.
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Roth-Isiqkeit A, Thyen U, Stoven H, Schwarzberger J, Schmuc-ker P. Pain among children and adolescents: restrictions in daily living and triggering factors. Pediatrics. 2005;115:e152-62.
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Yac W, Luo C, Ai F, Chen Q. Risk factors for nonspecific low--back pain in Chinese adolescents a case -control study. Pain Med. 2012;13:658-64.
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Perry MC, Straker LM, Oddy WH, O'Sullivan PB, Smith AJ. Spinalipain and nutrition in adolescents - an exploratory cross--sectional study. BMC Musculoskelet Disord. 2010;11:138.
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Janini SN, Dória-Filho U, Damiani D, Silva CA. Musculoskeletal pain in obese adolescents. J Pediat (Rio J). 2011;87:329-35.
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Zapata AL, Moraes AJ, Leone C, Doria-Filho U, Silva CA. Pain and musculoskeletal pain syndromes related to computer and video game use in adolescents. Eur J Pediatr. 2006;165:408-14.
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Smith L, Louw Q, Crous L, Grimmer-Somers K. Prevalence of neck pain and headaches: impact of computer use and other associative factors. Cephalalgia. 2009;29:250-7.
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De Vitta A, Martinez MG, Piza NT, Simeão SF, Ferreira NP. Pre-valence of lower back pain and associated factors in students. Cad Saude Publica. 2011;27:1520-8.
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Kelly G, Dockrel S, Galvin R. Computer use at school: its effect on posture in discomfort in schoolchildren. Work. 2009;32:321-8.
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Bostrom M, Dellve L, Thomée S, Hagberg M. Risk factors for generally reduced productivity - a prospective cohort study of young adults with neck or upper-extremity musculoskeletal symptoms. Scand J Work Environ Health. 2008;34:120-32.
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Jacobs K, Hudak S, McGiffert J. Computer-related posture and musculoskeletal discomfort in middle school students. Work. 2009;32:275-83.
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Lemos AT, Santos FR, Moreira RB, Machado DT, Braga FC, Gaya AC. Low back pain and associated factors in children and adoles-cents in a private school in Southern Brazil. Cad Saude Publica. 2013;29:2177-85.
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Publication Dates

Publication in this collection
Mar-Apr 2016

History

Received
24 Feb 2015
Accepted
30 June 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ☆
Please cite this article as: Silva GR, Pitangui AC, Xavier MK, Correia-Júnior MA, Araújo RC. Prevalence of musculoskeletal pain in adolescents and association with computer and videogame use. J Pediatr (Rio J). 2016;92:188-96.

Variables		Male	Female	Total
Number of volunteers		369	592	961
Age (years)		16.61 ± 1.35	16.40 ± 1.23	16.5 ± 1.3

Schooling
	1st year	146	218	364
	2nd year	106	167	273
	3rd year	112	212	324

Body mass (kg)		64.68 ± 13.60	56.15 ± 10.79	59.45 ± 12.64
Height (m)		1.71 ± 0.07	1.60 ± 0.06	1.64 ± 0.08

Family income
	1–2 minimum wages	235	461	696
	More than 2 minimum wages	134	131	265

Nutritional status
	Normal weight	300	459	759
	Overweight and obesity	75	127	202

Physical activity level
	Active	282	446	728
	Insufficiently active	88	145	233

Has a paid job
	Yes	65	106	171
	No	310	480	790

Computer use
	Yes	332	521	853
	No	37	71	108

Has a computer at home
	Yes	281	434	715
	No	88	158	246

Age at the start of use (years)		11.3 ± 2.8	11.3 ± 2.4	11.3 ± 2.6
Frequency of use (days/week)		5.5 ± 2.1	5.5 ± 2.1	5.5 ± 2.1
Weekly time of use (minutes)		1703.4 ± 1357.4	1731.7 ± 1596.5	1720.8 ± 1508.5

Use of electronic games
	Yes	297	310	607
	No	72	284	354

Frequency of use (days/week)		3.25 ± 2.55	1.82 ± 2.30	2.37 ± 2.50
Weekly time of use (minutes)		949.77 ± 1143.76	354.94 ± 675.39	583.34 ± 930.62
Total time of use of electronic devices (minutes)		2653.21 ± 2125.98	2086.67 ± 1955.69	2304.40 ± 2040.40

Variables		Cervical region					Scapular region
		Presence of pain	Absence of pain	OR	95% CI	p	Presence of pain	Absence of pain	OR	95% CI	p
Gender
	Female	126	466	1.65	1.16–2.35	0.005^a a Statistically significant – p < 0.05.	108	484	1.65	1.13–2.40	0.009^a a Statistically significant – p < 0.05.
	Male	52	317	1			44	325	1

Age
	14–16 years	98	386	1.26	0.91–1.75	0.165	85	399	1.30	0.92–1.85	0.135
	17–19 years	80	397	1			67	410	1

Employment
	Works	44	127	1.70	1.15–2.51	0.007^a a Statistically significant – p < 0.05.	26	145	0.95	0.60–1.50	0.809
	Does not work	134	656	1			126	664	1

Nutritional status
	Overweight and obesity	34	168	0.86	0.57–1.30	0.486	32	170	1.00	0.66–1.53	0.991
	Normal weight	144	615	1			120	639	1

Physical activity level
	Insufficiently active	42	191	0.96	0.66–1.40	0.823	30	203	0.73	0.48–1.13	0.157
	Active	136	592	1			122	606	1

Use of computer
	High (>3 h/day)	100	366	1.42	1.02–1.96	0.035^a a Statistically significant – p < 0.05.	72	394	0.95	0.67–1.34	0.763
	Low (<3 h/day)	80	415	1			80	415	1

Use of electronic games
	High (>1 h/day)	91	388	1.04	0.75–1.43	0.832	78	401	1.07	0.76–1.52	0.692
	Low (<1 h/day)	89	393	1			74	408	1

Total time of use
	High (>4 h/day)	103	375	1.45	1.04–2.01	0.026^a a Statistically significant – p < 0.05.	72	406	0.89	0.63–1.26	0.524
	Low (<4 h/day)	77	406	1			80	403	1

Variables		Upper limb					Thoracolumbar column
		Presence of pain	Absence of pain	OR	95% CI	p	Presence of pain	Absence of pain	OR	95% CI	p
Gender
	Female	134	458	1.56	1.13–2.20	0.010^a a Statistically significant – p < 0.05.	327	265	2.44	1.86–3.19	0.001^a a Statistically significant – p < 0.05.
	Male	58	310	1			124	245	1

Age
	14–16 years	103	380	1.18	0.86–1.62	0.302	224	260	0.95	0.74–1.22	0.685
	17–19 years	89	388	1			227	250	1

Employment
	Works	37	133	1.14	0.76–1.71	0.526	83	88	1.08	0.78–1.51	0.642
	Does not work	155	635	1			368	422	1

Nutritional status
	Overweight and obesity	53	149	1.58	1.10–2.28	0.013^a a Statistically significant – p < 0.05.	85	117	0.78	0.57–1.07	0.120
	Normal weight	139	619	1			366	393	1

Physical activity level
	Insufficiently active	41	191	0.82	0.56–1.20	0.309	92	141	0.93	0.69–1.26	0.697
	Active	151	577	1			300	428	1

Use of computer
	High (>3 h/day)	91	375	0.94	0.69–1.29	0.722	228	238	1.17	0.91–1.51	0.229
	Low (<3 h/day)	101	393	1			223	272	1

Use of electronic games
	High (>1 h/day)	98	380	1.07	0.77–1.46	0.699	218	261	0.89	0.69–1.15	0.380
	Low (<1 h/day)	94	388	1			233	249	1

Total time of use
	High (>4 h/day)	98	380	1.07	0.77–1.46	0.699	278	200	1.65	1.28–2.12	0.001^a a Statistically significant – p < 0.05.
	Low (<4 h/day)	94	388	1			221	262	1

Variables		OR	[95% CI]	p
Cervical column
	Gender (female)	1.93	1.32–2.83	0.001^a a Statistically significant – p < 0.05.
	Has a paid job (works)	1.75	1.17–2.62	0.008^a a Statistically significant – p < 0.05.
	Total time of use of electronic devices (>4 h/day)	1.61	1.13–2.28	0.007^a a Statistically significant – p < 0.05.

Scapular region
	Gender (female)	1.67	1.13–2.49	0.011^a a Statistically significant – p < 0.05.

Upper limbs
	Gender (female)	1.52	1.06–2.17	0.022^a a Statistically significant – p < 0.05.
	Nutritional status (overweight and obesity)	1.47	0.99–2.14	0.059

Thoracolumbar column
	Gender (female)	2.72	2.03–3.65	0.001^a a Statistically significant – p < 0.05.
	Total time of use (>4 h/day)	1.33	1.00–1.75	0.047^a a Statistically significant – p < 0.05.

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Introduction

Methods

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References

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History