Review on Health Impact of Mobile Phone

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Introduction To perform this study, it was necessary to understand how the mobile phone works. Wireless communication is existed for a long time since the ancient period people use fire, smoke, flag and etc. to communicate with each other from long distance(Schiller, 2003). Nowadays, with rapid development, mobile phones play a significant role in our daily lives, as it is indispensable, convenient and fast. Mobile phones function in radiofrequencies that range between 450, 800/900 and 1,800/1,900 MHz(Steele & Hanzo, 1999). The Advanced Mobile Phone Service (AMPS) is the first analog network produced, then during the 1990s, two digital networks CDMA and GSM are arrived(Anon., 2007). These second-generation (2G) networks has the ability to spread voice calls across several wireless spectrum and bring highly interactive experience to the mobile phone users. The 3G networks can be used by a number of users at the same time, and the frequency channels have 5-MHz bandwidths (Pederson, 1999). These cordless phones are used at very short ranges between a base station located at the telephone socket outlet within the house and the cordless phone handset(Adair, et al., 1999). Because the high mobility of mobile phone, it is very popular in modern world. And with more entertainment and useful functions as GPS and music are integrated, it becomes essential part in our lives. As discussed above, including mobile phone, development and use of wireless communication are increased rapidly in past a few decades. Widespread concerns have been raised about the possibility that mobile phones could affect people’s health. In this literature review, the emphases will be on the potential health dangers of the use of mobile phone based on the previous studies.

Brain Tumours The mobile phone owners are under the increasing health risks of the extensive use of mobile phone as they are severely exposed to the electromagnetic wave radiation which is emitted by mobile phone(Kshetrimayum, 2008). The potential health risk comes from absorbing the a comparatively large amount of electromagnetic energy, especially the human head, when mobile phone is used(Hardell, et al., 2007). Because the radiation of mobile phone is concentrated on a small area in human brain from hot-spot(Kshetrimayum, 2008). In previous studies, both initial and recent years’, most evidences on the relationship between brain tumor and mobile phone are insufficient based on the low numbers of the research. In the study of Inskip, et al.(2001, pp. 79-86), 782 hospital cases are enrolled with 489 malignant brain tumours, 197 with meningioma and 96 with acoustic neuroma. And there are only 11 glioma patients, 6 meningioma patients and 5

acoustic neuroma patients have at least 5 years’ regular use of mobile phone. Regular use of mobile phones gave OR(standardised incidence ratio)=0.8 (0.6 to 1.2) for glioma, OR=0.8 (0.4 to 1.3) for meningioma and OR=1.0 (0.5 to 1.9) for acoustic neuroma. Duration of use more than 5 years did not increase the risk for glioma and meningioma, but for acoustic neuroma, OR increased to 1.9 (0.6 to 5.9). Based on different types of glioma, anaplastic astrocytoma has OR=1.8 (0.7 to 5.1). In a case-control study of acoustic neuroma reported by Lonn, et al.(2004, pp. 653-9) from Karolinska Institute in Sweden, they were in collaboration with hospitals to indentify cases and check cases with the cancer registry. Published data were collected from 148 cases and 604 controls. Use of digital phones more than 5 years since the first use gave OR=1.2 (0.7 to 2.1). Use of analogue phones of a duration 5 to 9 years gave OR=1.3 (0.6 to 2.9), and for more than 10 years OR=1.8 (0.8 to 4.3). From those typical researches, there is a potential relationship between use of mobile phone and brain tumour. Long-term use of the mobile phone may increase the incidence ratio of the risk on brain tumour. But there are not strongly evidences to support this result and the potential relation so further more high quality studies are needed. Though the clue is not clear for the effect on the brain tumour, it also should be avoided as possible to reduce such risk from long-term use of mobile phone. The mobile phone users must learn some safety practices to avoid risk as possible such as keeping phone conversations short and use a plug-in earpiece to lessen the health risk imposed by these phones( Kshetrimayum, 2008; Repacholi, et al., 2001).

Bacteria on the phone As mentioned above, including the healthcare workers(HCWs), more and more people own mobile phones nowadays. Lots of innovations in mobile communications lead to significant improvements in quality of medical communication, healthcare efficiency and better patient control in many areas as diabetes and asthma (Ramesh, et al., 2008; Soto, et al., 2006). The better work experience and connectivity brought by the mobile communication devices(MCDs) are really accepted by the HCWs to reduce miscommunication and medical error (Brady, et al., 2009). In the recently study of Brady, et al.(2009, pp.295-300), approximately 78% HCWs expressed support by doctors’ use of mobile phones within hospital. The proportion for nurses and patients were 56% and 49% respectively. However, along with the benefits and popularity, some problems that are potential to increase the risk of patients are raised. These issues include environmental noise, patient confidentiality and bacterial contamination of MCDs(Brady, et al., 2009). Except the bacterial contamination of the MCDs, other issues are emphasized and

have resulted in comprehensive policy to avoid such risks(Bhattacharya, 2005).
  Table I Number of cellphone in which a specific type of bacteria was isolated(Brady, et al., 2006, p124)                                            Bacterial type Coagulase‐negative staphyloccocus Micrococcus spp. Bacillus spp.              Diptheroids              Methicillin‐sensitive Staphyloccus aureus    Streptococcus viridians Coliforms Methicillin‐resistant Staphyloccus aureus Enterococci faecalis Clostridium perfringens Number of mobile phones in which a specific  type of bacteria was isolated (total 105) 98 41 21 7 6 6 5 2 1 1

In the study of Brady, et al.(2006, pp.123-125), in 105 HCWs who owns mobile phone and are available to participate the mobile phone bacteria sampling, 84.5% of them took their mobile phones to hospital every day and 40.1% used mobile phone at least once per day during work. As figured in Table I, the evidence of bacteria contamination is found on approximately 97% of phones, and the bacteria that can cause nosocomial infection are grown on 14.3% sampled phones. Besides, 38.1% phones are contaminated by one species, 38% are contaminated by two different species and 20.95% are contaminated by three or even more different bacteria species. This study shows the very high rate of mobile phones are contaminated by bacteria which may increase the risk of patient’s health, especially in operating theatre environment. To avoid these issues as possible, previous studies have discussed and recommended many ways as staff education, strict hand hygiene and restrictions of mobile phone use. Staff education can be improved by group study or posting posters and leaflet to the area where they congregate to remind them(Naikoba & Hayward, 2001). The importance of strict hand hygiene is strongly emphasized and recommended by the most authors(Goldblatt, et al., 2007; Karabay, et al., 2007; Namias, et al., 2000). Some reports call for complete ban on mobile phone in general clinic environment but it is not feasible as such MCDs are widely used in general clinical care. The most possibility is restrictedly control the use of mobile phones and completely ban the mobile phones in some special areas(Jeske, et al., 2007).

Auditory system effect In the study of Aal-Abduljawad(2008, pp. 72-74), volunteers are divided into 3 groups. Group one used mobile phones frequently and spoken approximately 3-4 hours per

day for two years. Group two used mobile phones for 1-2 hours per day for two years. Group three never used mobile phones (control group). At last, the result showed four volunteers from group one had reported ear pain, headache, tinnitus, weddings noise, and party noise in the used ear but only one suffered tinnitus and headache from group two. From group three, there two volunteers suffered from tinnitus. In another study of Noritoshi, et al.(2003, pp. 1390-1394) on the effect of auditory system, healthy normal volunteers were exposed to mobile phone radiation for 30 min and were suffered different electrophysiological examinations, including ABR (auditory brainstem responses) and MLR (middle latencies responses). From the result that no electrophysiological changes in ABR, the author indicated that “short-term exposure to mobile phone EMR (electromagnetic radiation) does not affect stimulus transmission along the auditory pathway”. Based on the small number of participators and limited time, long-term use of mobile phone seems increasing the risk of effects on auditory system much more than short-term use, but unfortunately, current lack of solid scientific evidence on the biological effects of auditory system of EMFs(electromagnetic fields) leads to confusion. Therefore, new studies are urgently needed to further clarify and identify the effects of EMR on the human body and also more strongly evidence needed(Kaprana, et al., 2008).

Metal allergens and skin hypersensitivity On the topic of Metal allergens of growing significance: Epidemiology, immunotoxicology, strategies for testing and prevention, Forte, at el.(2008, pp. 145-162) states: “Metal-induced allergic contact dermatitis (ACD) is expressed in a wide range of cutaneous reactions following dermal and systemic exposure to products.” Metals such as aluminium, chromium, copper, gold, iridium, platinum and titanium are the common elements of mobile phone which may cause skin hypersensitivity. The report of Basketter(2008, pp. 267-273) indicates that although the total content of such metal elements are limited by European Union, the diffusion of metal-induced ACD is still quite high. In another study, Kadyk, et al.(2003, pp. 1037-1048) focused on the quality of life of people suffered by the skin hypersensitivity. It indicated that responders were bothered most by itching, skin irritation, and persistence of the condition. Of the four scales presented in the QoL(quality of life) questionnaire, the emotions scale had the worst composite QoL score, followed by symptoms, functioning, and occupational impact. Patients were significantly more bothered by the appearance of their skin with ACD of the face.

within the occupational impact and functioning scales, hand skin hypersensitivity and occupationally related ACD were associated with worse QoL scores. As known, mobile phone contacts hand and face frequently during daily life, so such skin hypersensitivity may lead further disease and affect emotions significantly. The patients will suffer the health risk both on mental and physical. Forte, et al.(2008, pp. 145-162), also discussed the approaches for ACD prevention and therapy such as observe the maximum allowable metal levels, optimize metallurgic characteristics and take personal protection. Whereas, these avenues are quite general and lack of details for precaution and prevention on the conditions of mobile phone use. In this aspect of health dangers of mobile phone use, there are not lot of studies focus on the metal allergens and skin hypersensitivity with mobile phone use.

Conclusion On the basis of health dangerous from the mobile phones study, most potential and existed risks have been discussed and reviewed in this literature review. Though there are lots of previous studies emphasis on the health risk related with mobile phone, only the directly contactable factors can give clear and strong evidences. Most studies on brain tumour, auditory system, eye, central nervous system and etc. do not have sufficient support evidences, but there are still potential risks with use of mobile phone especially long-term use. Further more, more quality studies are needed to find the effects of mobile phones on human body. As a kind of mobile communication devices, this study should absorb more relevant information on other MCDs, and this will be helpful to investigate and cover more aspects of the effects from mobile phone.

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