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The Association Between Smartphone Use and Breast Cancer Risk Among Taiwanese Women: A Case-Control Study

Authors Shih YW, Hung CS , Huang CC , Chou KR , Niu SF, Chan S , Tsai HT 

Received 16 June 2020

Accepted for publication 18 September 2020

Published 29 October 2020 Volume 2020:12 Pages 10799—10807

DOI https://doi.org/10.2147/CMAR.S267415

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 2

Editor who approved publication: Professor Harikrishna Nakshatri



Ya-Wen Shih, 1 Chin-Sheng Hung, 2, 3 Cheng-Chiao Huang, 4 Kuei-Ru Chou, 1, 5– 7 Shu-Fen Niu, 8, 9 Sally Chan, 10 Hsiu-Ting Tsai 1, 8

1School of Nursing, College of Nursing, Taipei Medical University, Taipei, Taiwan; 2Department of Surgery, School of Medicine, College of Medicine, Taipei Medical University, Taipei, Taiwan; 3Division of General Surgery, Department of Surgery, Shuang Ho Hospital, Taipei Medical University, New Taipei City, Taiwan; 4Division of Breast Surgery, Department of Surgery, Taipei Medical University Hospital, Taipei, Taiwan; 5Center for Nursing and Healthcare Research in Clinical Practice Application, Wan Fang Hospital, Taipei Medical University, Taipei, Taiwan; 6Department of Nursing, Taipei Medical University-Shuang Ho Hospital, New Taipei City, Taiwan; 7Psychiatric Research Center, Taipei Medical University Hospital, Taipei, Taiwan; 8Post-Baccalaureate Program in Nursing, College of Nursing, Taipei Medical University, Taipei, Taiwan; 9Department of Nursing, Shin Kong Wu Ho Su Memorial Hospital, Taipei, Taiwan; 10UON Singapore Campus, Univesrity of Newcastle, Newcastle, NSW, Australia

Correspondence: Hsiu-Ting Tsai Email [email protected]

Introduction: Breast cancer is a common malignancy worldwide. Smartphones have gradually become indispensable to our modern lives and have already changed lifestyles of human beings. To our best knowledge, no study has investigated the relationship between smartphone use and breast cancer. This case-control study purposely investigated the relationship between smartphone use and breast cancer risk.
Materials and Methods: This was a case-control study comprising 894 healthy controls and 211 patients with breast cancer. All participants were asked to respond to standard questionnaires to collect information on sleep quality, smartphone addiction, and smartphone use.
Results: Participants with smartphone addiction had a significantly higher 1.43-fold risk of breast cancer. Individuals with the habitual behavior of smartphone use > 4.5 minutes before bedtime had a significantly increased 5.27-fold risk of breast cancer compared to those who used a smartphone for ≤ 4.5 minutes before bedtime. Additionally, a closer distance between the smartphone and the breasts when using the smartphone exhibited a significantly increased 1.59-fold risk. Participants who carried their smartphone near their chest or waist-abdomen area had significantly increased 5.03-fold and 4.06-fold risks of breast cancer, respectively, compared to those who carried the smartphone below the waist. Moreover, there was a synergistic effect of smartphone addiction and smartphone use of > 4.5 minutes before bedtime which increased the breast cancer risk.
Conclusion: Excessive smartphone use significantly increased the risk of breast cancer, particularly for participants with smartphone addiction, a close distance between the breasts and smartphone, and the habit of smartphone use before bedtime.

Keywords: smartphone addiction, breast cancer, women, sleep quality

A Letter to the Editor has been published for this article.

A Response to Letter has been published for this article.

Introduction

According to the International Telecommunication Union (ITU), the number of smartphone subscriptions over the last decade increased ninefold reaching 7 billion users worldwide in 2014.1 In the past decade, smartphones have gradually become one of our indispensable accessories, with the majority of devices providing access to portable internet service, and people usually text-messaging instead of talking, and with the addition of applications (apps) for e-shopping or binge-watching TV series through the smartphone. With advances in science and technology, the functions of smartphones have greatly increased, they have already changed human lifestyles worldwide,14 and their impacts need to be assessed.

Breast cancer is the most commonly diagnosed malignancy among females, with about 1.38 million women being diagnosed with breast cancer worldwide each year.5 According to the cancer registry statistics of the Health Promotion Administration (HPA) in Taiwan, the incidence of breast cancer has increased in the past 20 years, it has exceeded cervical cancer, and it has become the most common female cancer since 2003.6

People are spending more and more time on their phones, with use having risen sharply in recent decades.1 Radiofrequency radiation emitted by smartphones is thought to be associated with greater concerns about health risks and cancer-related issues.712 It was found that radiofrequency radiation exposure caused mammary cell damage and reactive oxygen species (ROS) formation,13,14 which are the primary causes of DNA strand breaks that can lead to cell death.12,15 Also, it was reported that as smartphones emit light, they can suppress melatonin production, a sleep-promoting hormone.16 Numerous current evidence has demonstrated that excessive use of a smartphone (due to internet addiction) before bedtime can result in poor sleep quality.17,18 A meta-analysis study by Alimoradi et al19 indicated that internet addiction is significantly associated with sleep problems (with an overall pooled odds ratio (OR) of 2.20 and 95% confidence interval (CI) of 1.77~2.74) and sleep duration (with an overall pooled standardized mean difference (SMD) of −0.24 h and 95% CI of −0.38 to -0.10 h). Chronic suppression of melatonin, poor sleep quality, and delayed night sleep can lead to circadian rhythm disturbances, especially when people use the smartphone for surfing the internet before bedtime day after day, which may produce negative health outcomes.18

Moreover, academic researchers have demonstrated that smartphone use increases incidences of brain tumors,2022 parotid cancer,23,24 acoustic neuromas,23,25 non-Hodgkin’s lymphomas,26 and testicular cancer.27 We hypothesized that excessive use of smartphones can increase the risk of breast cancer by non-ionizing radiofrequency exposure or by suppressing melatonin production.12,15,28,29 However to our best knowledge, no study has investigated this relationship. The purpose of this study was to investigate the association between smartphone use and breast cancer risk.

Materials and Methods

Study Design and Participants

This was a case-control study. Participants were recruited between November 2017 and April 2018 from the breast surgery outpatient department of a medical university hospital that provides professional treatment and consultation for breast disease. All participants from the hospital provided written informed consent before they were allowed to participate, and the study protocol was approved by the medical university hospital’s institutional review board (N201709040). The inclusion criteria for the case group included (1) participants aged over 20 years and capable of responding to our questionnaires; (2) having a diagnosis of breast cancer with a proven pathological record of histological confirmation by the International Classification of Disease ninth revision code (ICD-9): 174.0~174.9; (3) having been diagnosed with breast cancer no more than 3 months prior to the recruitment interview and without being comorbid with other cancers; and (4) having agreed to participate in the study. The inclusion criteria for the control group included: (1) participants aged over 20 years and capable of responding to our questionnaires; (2) with no history of any cancer; and (3) agreeing to participate in the study. To increase the sample size and generalizability, we set the ratio of cases to controls as 1:4. Our controls were recruited from the outpatient department and also from an online survey on the internet. We embedded a questionnaire link to a women’s association website. For our controls from the online survey, the selection criteria were the same as for participants who were from the outpatient department. All participants were asked to pay attention to the instructions of the standardized questionnaires before they began to fill them out. Sonographic, ultrasound, or mammographic results were also collected from chart-records or provided by participants themselves. Those with no abnormalities in the above screening records were assigned as potential controls.

Instruments/Data Collection

The self-constructed questionnaire collected demographic information, including age, educational level, results of breast cancer screening records, family history of breast cancer, and details of behaviors of smartphone use, such as the frequency and duration of smartphone use per day, placement of the smartphone when carrying it, use of a smartphone before sleep at night, sleep quality, and years of surfing the internet with a smartphone.

Sleep quality was assessed using the Chinese version of the Pittsburgh Sleep Quality Index (PSQI) translated by Tsai et al based on the original version.30,31 The PSQI is a self-rated measure of sleep quality, that consists of seven components, including subjective sleep quality, sleep latency, sleep time, sleep efficiency, sleep disturbances, hypnotic drug usage, and daytime dysfunction. Possible scores of the Chinese version of the PSQI range 0~21, with a higher score indicating a worse sleep quality.31 An overall PSQI score of >5 can be used to identify sleep problems. The Chinese version of the PSQI had an overall reliability coefficient of 0.82~0.83 for all participants, which indicates a high degree of internal consistency, and a test-retest reliability coefficient of 0.85.31

The Smartphone Addiction Inventory-Short Form (SPAI-SF) was used to evaluate smartphone addiction;32 it is a 10-item self-reporting instrument consisting of four dimensions, including compulsive behavior, functional impairment, withdrawal, and tolerance. The total SPAI-SF score is obtained by summing the scores of each dimension, on a 4-point Likert scale ranging from 1 (strongly disagree) to 4 (strongly agree). The SPAI-SF demonstrated good internal consistency with Cronbach’s α of 0.84. The area under the receiver operating characteristics (ROC) curve (AUC) was 0.709, and a cutoff point of 24/25 was best for discriminating cases of smartphone addiction from diagnostic negatives (with diagnostic accuracy of 74.6%, Youden index of 0.360, and specificity of 80.5%). Therefore, participants with a total score of ≥25 points were determined to be people with smartphone addiction.32

Sample Size Calculation and Statistical Power

The sample size was calculated based on a previous study by Hardell et al22 assuming 95% confidence intervals (CIs) and p=0.05, and adjusting for other confounders. Our sample size had at least 90% power to detect a 1.7-fold increased risk in the susceptibility to breast cancer and smartphone addiction.

Statistical Analysis

Distributions of participant characteristics were examined by a χ2 test for categorical variables. An independent t-test was used to examine differences in continuous variables between two groups. An ROC curve was used to evaluate the diagnostic capability of how many minutes a smartphone was used before night sleep to differentiate participants from the case and control groups. The highest Youden index was chosen for the best cutoff point of smartphone usage (minutes) before night sleep. The Youden index represents a summary measurement of the ROC curve for the accuracy of a diagnostic test.33 The AUC, sensitivity, specificity, accuracy, positive predictive value (PPV), and negative predictive value (NPV) were calculated. Otherwise, the likelihood ratios of positive (> the cutoff point of minutes of using a smartphone before night sleep; LR+) or negative (≤ the cutoff point of minutes of using a smartphone before night sleep; LR-) were assessed. Multivariable logistic regressions were used to estimate adjusted ORs (AORs) with 95% CIs of the association between smartphone use and breast cancer risk, after adjusting for other covariates. Candidate variables with a p value of ≤0.10 in the univariate analysis or had been proven as a breast cancer risk were included in the multivariable model.34 We analyzed data using SPSS vers. 18.0 (SPSS Released 2009. PASW Statistics for Windows, Chicago, IL, USA).

Results

Distributions of demographic characteristics and smartphone use between patients with breast cancer and healthy controls are shown in Table 1. There were significant differences in age, educational level, smartphone addiction, the time of using a smartphone before night sleep, placement of the smartphone when not in use, the position when using a smartphone, and sleep quality between the two groups. Compared to the controls, patients with breast cancer were significantly older, had a lower educational level, had a higher percentage addicted to smartphones, had poorer sleep quality, and were more likely to use a smartphone before night sleep as well as preferred to place their smartphone closer to their breasts. There was no significant difference in the family history of breast cancer or years having surfed the internet with a smartphone between these two groups. In addition, in the control group, there was no significant difference in distributions of demographic characteristics and smartphone use behaviors between participants recruited from the online-survey and those from the clinical outpatient department (data not shown).

Table 1 Distributions of Demographic Characteristics and Smartphone Use Behaviors Among Healthy Controls and Patients with Breast Cancer (N=1105)

Associations between smartphone use behavior and breast cancer risk are summarized in Table 2. People with smartphone addiction were more common among participants with breast cancer (61.6%) than among healthy controls (54.4%). After adjusting for confounding factors, participants with a smartphone addiction had a significantly increased 1.43-fold risk (AOR=1.43, 95% CI=1.01~2.02) of breast cancer compared to those without an addiction. Participants with habitual smartphone use before night sleep also had an increased risk of having breast cancer. The Youden index showed that the best cutoff value of spending time using a smartphone before night sleep was determined to be 4.5 min. The AUC was 81% (p<0.0001; 95% CI=0.77~0.85), and the sensitivity, specificity, PPV, NPV, accuracy, and likelihood ratios of positive and negative results were 71%, 89%, 60%, 92%, 85%, 7.1, and 0.31, respectively. The Youden index and optimal cutoff points are shown in Supplementary Table 1. Individuals with habitual use of a smartphone before night sleep of >4.5 min had a significantly increased breast cancer risk (AOR=5.27, 95% CI=3.52~7.88) compared to those who used a smartphone for ≤4.5 min before night sleep after adjusting for confounders. The distance between the breasts and smartphone when in use was significantly associated with the breast cancer risk. Participants who used a phone while bending the head down (holding the smartphone in the hand, such that the distance between the smartphone and breasts was around 10 cm) had a significantly increased 1.59-fold risk (AOR=1.59, 95% CI=1.00~2.53) of breast cancer compared to those put the phone on a desk (with the distance between the smartphone and the breasts of around 35 cm) when using the smartphone. The major region where the smartphone was placed when not in use was also significantly related to the risk of breast cancer. Individuals who placed the smartphone in the chest area (such as keeping it in a bra or hanging it around the neck near the breasts) or in the waist-abdominal area had significantly increased 5.03-fold risk (AOR=5.03, 95% CI=1.75~14.44) and 4.06-fold risk (AOR=4.06, 95% CI=2.11~7.78), respectively, of breast cancer compared to those who carried their smartphone in the area below the waist.

Table 2 Adjusted Odd Ratio (AOR) and 95% Confidence Interval (CI) of Smartphone Use Behaviors and Breast Cancer Risk (N=1105)

The synergistic effect between smartphone addiction and time spent on the smartphone before night sleep on the breast cancer risk is shown in Table 3. A synergistic effect between smartphone addiction and smartphone use before night sleep was found. Participants with smartphone addiction and habitual use of a smartphone before night sleep of >4.5 min or non-addicts but with habitual use of a smartphone before night sleep of >4.5 min had significantly increased 6.88-fold risk (AOR=6.88, 95% CI=4.07~11.61) and 3.24-fold risk (AOR=3.24, 95% CI=1.62~6.44), respectively, of breast cancer compared to those who had neither smartphone addiction nor smartphone use of >4.5 min before night sleep.

Table 3 Adjusted Odd Ratio (AOR) and 95% Confidence Interval (CI) of the Synergistic Effect Between People with Smartphone Addiction and the Time Spent on Smartphone Use Before Night Sleep on the Breast Cancer Risk (N=1105)

Discussion

To the best of our knowledge, we are the first to find that excessive smartphone use significantly increased the risk of breast cancer, particular for participants with a smartphone addiction, who maintained a close distance between the breasts and smartphone, and who had the habit of smartphone use before bedtime. Moreover, there was a synergistic effect between smartphone addiction and habitual smartphone use of >4.5 min before night sleep of increasing the breast cancer risk.

White et al35 conducted a prospective cohort study to investigate the relationship between the quality of sleep and breast cancer. They identified 41,474 participants who were breast cancer-free at the baseline and completed baseline questionnaires on sleep characteristics. After 7 years of follow-up, 2736 new breast cancer cases (invasive and ductal carcinoma in situ) had been diagnosed. They found that participants who suffered from difficulty sleeping ≥4 nights per week were at an overall increased risk of breast cancer (hazard ratio (HR)=1.32, 95% CI=1.09~1.61) compared to those with difficulty sleeping <1 night per week.35 Our investigation results were consistent with those of White et al, as we found that the quality of sleep among patients with breast cancer was significantly worse (p=0.01) than that of healthy controls.

Smartphone addiction was reported to have negative impacts on health because of making changes in a person’s lifestyle, including a general decrease in physical activity, neglecting one’s health status, and avoiding outside activities, in order to spend more time on the internet.2 Additionally, some laboratory studies also demonstrated that radiofrequency fields accelerate the development of sarcoma colonies in the lungs, mammary tumors, skin tumors, hepatomas, sarcomas, and brain tumors.711 In our study, we found that participants with a smartphone addiction had a significantly increased 1.43-fold risk of breast cancer compared to those without addiction. Our results suggest that people with smartphone addiction could have massive radiofrequency exposure compared to people without smartphone addiction,36,37 therefore increasing their risk of developing breast cancer.

Individuals with habitual use of a smartphone of >4.5 min before night sleep had a significantly increased breast cancer risk (AOR=5.27, 95% CI=3.52~7.88) compared to those who used a smartphone for ≤4.5 min before night sleep after adjusting for confounding factors. This result was also supported by Chang et al,16 who conducted a randomized controlled trial to estimate the effect of an electro-device book on melatonin expression. They randomized their participants into two conditions: (i) reading an electro-device book, such as an iPad notebook or Kindle for 4 h before bedtime for five consecutive evenings, and (ii) reading a printed book for the same duration. Their results showed that the electro-device condition suppressed evening levels of melatonin by 55.12% ± 20.12%, whereas the printed-book condition showed no suppression as measured on the fifth night (p<0.001). Also, the electro-device condition delayed the onset of melatonin release. The onset of melatonin release was significantly deferred (p<0.001) among participants in the electro-device condition (22:31 ± 00:42) compared to those in the printed-book condition (21:01 ± 00:49).16 They highlighted that use of electro-devices before bedtime prolonged the time of falling asleep, delayed the circadian clock, suppressed levels of the sleep-promoting hormone melatonin, and reduced the amount of and delayed the timing of rapid eye movement (REM) sleep.16,18 Some studies also reported that circadian disruption favors the induction and/or promotion of malignant breast tumor development.35,3840 A similar result was found by White et al35 that the risk of breast cancer was significantly elevated in women who reported having a light or television on in the room while sleeping. We suggest that using a smartphone before bedtime causes participants to be exposed to short-wavelength-enriched light emitted by these electronic devices, which contributes to suppression of melatonin expression at night and a phase-shift in the biological clock.18 Because melatonin plays an important role in inhibiting the release of estrogen, a risk factor for breast cancer, and also for suppressing the development of breast cancer,3841 we considered that inhibiting melatonin expression and inducing circadian disruption due to smartphone use before bedtime can result in a propensity for breast cancer development.

Participants who were used to bending their head down (holding the smartphone in the hand; with a distance between the smartphone and breasts of around 10 cm) when using a smartphone had an increased 1.59-fold risk of having breast cancer compared to those who put the phone on a desk (with the distance between the smartphone and breasts of around 35 cm). An experimental study demonstrated that using smartphones and Wi-Fi radiation sources which were at least 10 cm away may provide useful distance against oxidative stress, apoptosis, and overload Ca2+ entry in cancer. Radiofrequency radiation exposure is significantly associated with intracellular ROS production when smartphones or WiFi sources are placed within 10 cm of cells, which induced excessive oxidative responses and apoptosis via transient receptor potential vanilloid 1 (TRPV1)-induced cytosolic Ca2+ accumulation in breast cancer cells.42 This result is consistent with our study, of a shorter distance between the breasts and smartphone increasing the risk of breast cancer. Therefore, we suggest that a closer distance between the smartphone and breast benefits exposure and transmission of radiofrequencies emitted from the smartphone to the breasts, and contributes to ROS production, thereby promoting the development of breast cancer,43 and thus maintaining a sufficient distance between the smartphone and breasts of at least 35 cm in all situations are strongly recommended.

Individuals who were used to placing the smartphone on the region near the chest area or waist-abdomen area when it was not in use had a significantly increased 5.03-fold risk and 4.06-fold risk, respectively, of having breast cancer compared to those who carried the smartphone in the area below the waist. Regarding the shorter distance between the breast and smartphone placement, that could increase the risk of breast cancer, an interesting case report consisted of four young women aged 21~39 years, who exhibited no family history of breast cancer and tested negative for BRCA1 and BRCA2. Their breast imaging was reviewed and demonstrated clusters of multiple tumor foci in the breast directly under the area of phone contact, and further, participants who regularly carried their mobile phones close to their breast area for a period of up to 10 h a day were found to be at higher susceptibility of developing tumors in their breasts.44

It is noteworthy that we found a synergistic effect between smartphone addiction and smartphone use of >4.5 min before night sleep increasing the breast cancer risk. Participants who were both addicted to their smartphone and used their smartphone for >4.5 min before night sleep and participants who were not addicted to their smartphones but used the smartphone for >4.5 min before night sleep, respectively, had increased risks of breast cancer of 6.88-fold and 3.24-fold compared to those who were neither addicted to their smartphone nor used their smartphone for >4.5 min before night sleep. We suggest that the potential mechanism relating to the synergistic effect of smartphone addiction and using a smartphone for >4.5 min before night sleep on the risk of breast cancer could be due to these two risk factors being prone to expose participants to radiofrequencies and circadian disruption. Smartphone-emitted radiofrequency radiation induces the creation of ROS, which contribute to DNA mutations and carcinogenesis.13 Circadian disruption results in the inhibition and delay of melatonin expression,17 consequently decreasing the quality of sleep and benefiting the release of estrogen, which promotes the development of breast cancer.4547

Limitations

This study provides important findings that incorrect smartphone use habits can be potential risk factors for breast cancer. However, there were some limitations to our study. First, all patients with breast cancer were recruited from a hospital, while the control group was recruited from both the hospital and an online survey. Among the control group, the inclusion criteria for controls were identical, and there were no significant differences in the distributions of demographic characteristics or smartphone use behaviors between the healthy controls recruited from the hospital and those from the online survey. Despite this, we noted that demographics differed between the case and control groups; therefore, we used a univariate analysis to adjust all covariates in the multivariable model. We consider that this limitation should not have induced non-comparability between the case and control groups or any overestimation of our results. Second, placement of the smartphone and posture when using a smartphone may vary in a day. Exposure to radiation depends on the length of time and frequency of use, which vary from individual to individual, and these variables might not be accurately assessed by a questionnaire. Third, all of the instruments were assessed using self-reporting, and the major problem with self-reporting is recall bias. Finally, some variables of the self-constructed questionnaire for demographic data collected, such as the use of smartphones before night sleep, posture when using a smartphone, and placement of the smartphone, might not have provided precise answers. Consequently, future studies might consider using objective measuring instruments (a tracking app to assess time spent on surfing the smartphone each day and a tracking app of distance/placement when using the smartphone) could more precisely and objectively measure the variables examined.

Conclusions

Smartphone addiction, smartphone use of >4.5 min before bedtime, and a close distance between the smartphone and the bosom significantly increased the breast cancer risk. Moreover, the combination of smartphone addiction and smartphone use of >4.5 min before bedtime synergistically increased the breast cancer risk.

Ethics Approval and Consent to Participate

This study was approved by the Ethics Committee of the Taipei Medical University Hospital Institutional Review Board (no. N201709040) (source deleted for blinded review) and conformed to the Declaration of Helsinki. All participants provided written informed consent before study enrollment. None of the patients who provided consent was eliminated from the study. All methods were performed in accordance with relevant guidelines and regulations.

Acknowledgments

Our appreciation is extended to every researcher and participant who contributed to this study. This study was supported by grant nos. MOST 106-2314-B-038-013-MY3 and MOST 109-2314-B-038-110- from the Ministry of Science and Technology, Taiwan. The funders had no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Author Contributions

All authors made a significant contribution to the work reported, whether in the conception, study design, execution, acquisition of data, analysis and interpretation, or in all these areas; took part in drafting, revising, or critically reviewing the article; gave final approval of the version to be published; have agreed on the journal to which the article has been submitted; and agree to be accountable for all aspects of the work.

Disclosure

The authors report no conflicts of interest with regard to this work.

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