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Original paper

The role of nickel allergy in hand dermatitis and its impact on handling cupronickel currency coins.
A comparative cohort study from Kuwait

Nawaf Almutairi
,
Fahad Almutawa

Adv Dermatol Allergol 2017; XXXIV (4): 313–321
Online publish date: 2017/08/01
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- The role of nickel.pdf  [0.17 MB]
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Introduction

Contact allergy is an important public health problem with a significant personal, social and economic impact on the affected individuals, and the society at large. Nickel exposure is the most common cause of contact allergy in the general population. Also, nickel allergy is a well-known risk factor for developing hand eczema [1, 2]. Common sources of nickel allergy are jewelry and other metal items coming in contact with the skin such as belt buckles, watches, clothing metal items such as buttons, clips, hooks, buckles, clippers, etc. Skin contact with any item that releases nickel in sufficient amounts may cause contact allergy and dermatitis, as shown recently by the increasing use of metallic mobile phones and laptop computers [3]. One study from Sweden showed that the prevalence of nickel allergy in students aged 15–23 years was 13% in females and 2.5% in males [4], and that 24% of female and 7.4% of male dermatitis patients were allergic to nickel [5]. However, a more recent study from Sweden shows a decreasing prevalence of nickel allergy especially in young women [6]. And, a reduction in prevalence of nickel allergy has also been seen in other EU states like in Denmark, Germany and Italy [7]. The decrease in prevalence has been largely due to stricter EU norms for regulation of nickel content in REACH items. Wherein, the items intended for prolonged contact with the skin are not allowed to release nickel at a rate > 0.5 µg/cm2/week. Allergic nickel dermatitis still remains a problem in EU nations. This might be attributable to lack of restrictions on many short and frequent contacts with everyday items and products containing nickel, such as coins and tools [8]. Some of those items in the work tools and materials may release nickel in high amounts [9]. Occupations requiring short and repeated contact with nickel and involving tools and objects such as cashiers, sales assistants, hairdressers, health care workers, dental assistants etc. are at risk of nickel allergy [10]. This may result in hand eczema, a chronic condition that can result in poor quality of life, reduced ability to work, and large costs to individuals and the society [11]. Handling of nickel containing coins may be a potential contributor to occurrence or aggravation of signs and symptoms of dermatitis in nickel sensitized individuals [12].

Aim

Many studies have been reported, mainly from Europe, on the risk of allergic dermatitis from handling coins and its various aspects [13, 14]. No such study has been conducted in Kuwait or the Middle East. However, cupronickel coins have been in use since 1961 in Kuwait. This prompted us to conduct the present study.

Material and methods

All patients diagnosed in the past with hand dermatitis presenting to the dermatology departments of two tertiary level government hospitals, in two different governorates in Kuwait between September 2014 and September 2015 (1 year duration) were enrolled. The study was approved by ethics committees of the respective hospitals. All the recruited patients had given written informed consent to participate in the study, and also to undergo patch tests and coin handling tests in spite of being made aware of a remote chance of sensitization in few of non-sensitized patients. All the recruited patients who were found eligible and were all screened for nickel allergy. The screening was done by patch tests using European baseline series (Chemotechnique DiagnosticsTM, Velling, Sweden) with nickel sulphate (5% petrolatum) within IQ chambers (Chemotechnique Diagnostics TM, Velling, Sweden). A total of 500 patients underwent patch testing during the study period. Of these, 100 patients with positive patch tests (group I: nickel-allergic,) and 100 matched patients with negative patch tests to nickel (group II: nickel non-allergic) were included for further testing with coin handling. A detailed clinical, occupational, exposure history and clinical examination was conducted and recorded in a performa. Ninety-one patients from group I (29 males, 62 females) and 87 from group II (38 males, 49 females) completed the study and were available for analysis.

Exclusion criteria


– Subjects with hand dermatitis exacerbation at the time of the procedure.
– Subjects with severe reactions in the patch test (angry back).
– Pregnancy and lactation.
– Subjects on immunosuppressive medications.

Special instructions

Patients were advised to refrain from wearing any nickel-containing clothes or articles (watches, zips, artificial jewelry, medals etc.) for 1 week prior to the date of exposure to nickel-releasing coins until the completion of the second phase of the study (i.e. exposure to nickel coated coins 3 months later). Handling of Kuwaiti coins in a day-to-day life was allowed.
Every patient was provided with a nickel spot test kit (CHEMO-NICKEL TEST®, Chemotechnique Diagnostics AB, Malmo, Sweden) to facilitate identifying nickel-containing metals (to reduce prolonged and direct contact with higher nickel-releasing items).
The same subjects served as controls in each group after 3 months. We repeated the same steps with them but with coated nickel coins.

Specifications of the Kuwaiti coins

Kuwaiti coins 100 fils, 50 fils and 20 fils are made from cupronickel alloy (one Kuwaiti dinar is 1000 fils). The specification of these coins is shown in Table 1 [15].

Preparation of coins

Nickel releasing coins: The coins were in circulation and not cleaned or pretreated prior to use by the subjects. This was done to ensure that study conditions were kept as close as possible to the real life situation.
Non-nickel releasing coins (control coated nickel coins): The same nickel releasing coins used in the first stage of the study were coated with transparent nitrocellulose lacquer (free of formaldehyde, toluene, or dibutyl phthalate). Each coin received three coats of the nitrocellulose coats.
These coated coins were then tested with dimethylglyoxime (DMG) nickel spot test each day before running the test to ensure the efficiency of the coating in preventing the release of nickel from the coins onto the skin. Any coin that gave positive reaction to the DMG test was replaced by another coated and tested coin. We did the same procedure at the end of the day to test if there was no nickel release.

Patch testing

European baseline series (Chemotechnique DiagnosticsTM, Velling, Sweden) with nickel sulphate (5% petrolatum) within IQ chambers (Chemotechnique Diagnostics TM, Velling, Sweden). Nickel sulfate hexahydrate (purity ≥ 98.5%) is used in this patch. The patch was applied to the upper back for 48 h, and read at 48 h, 72 h and 96 h. Nickel positivity was defined as revealing erythema and/or edema at 96 h utilizing the standard International Contact Dermatitis Research Group Criteria (ICDRG) [16].

Determining nickel release from the coins

The amount of nickel released from the Kuwaiti cupronickel coins was determined using the standard method according to EN1811 (EU Nickel Directive), by immersing in an artificial sweat solution for 1 week [9]. Kuwaiti cupronickel coins of 100 fils, 50 fils and 20 fils denominations obtained from the circulated coins issued by the Central Bank of Kuwait were used for the study. An artificial sweat solution was prepared as per the EN1811 (EU Nickel Directive) resulting in the desired composition (0.5 wt % sodium chloride, 0.1 wt % lactic acid, 0.1 wt % urea) and normal ultra pure water (not aerated as described in the standard) [17]. The pH of the solution was adjusted to pH 6.5 using the ammonium hydroxide solution. An artificial sweat solution was stored in darkness and used within 3 h of preparation. The pH was measured before and after immersion.

Reagents and instruments

A Hitachi Model 180-50 atomic absorption spectrometer (Hitachi Ltd., Tokyo, Japan) equipped with a Hitachi GA-3 graphite furnace atomizer, Tristar grade nitric acid (BDH laboratory supplies, Poole, UK), Milli-Q ultra pure water (18 MΩ cm; Millipore, Watford, UK), Graduated sample tubes (10 ml; Saestedt AG, Nurnbrecht, Germany) were used throughout the study.
The coins were placed in 10 ml of a freshly prepared artificial sweat solution in a 10 ml volumetric flask. One milliliter of the solution served as a blank. The samples were shaken at 200 rpm in a bath at 37°C for 1 week. Successive 1 ml samples were removed daily and nitric acid 1% was added to each sample to stabilize the extracted nickel. The samples were then stored in a glass vial in a refrigerator until analysis. The quantity of nickel released was analyzed by the atomic absorption spectrometer. The nickel concentration in the solution was calculated at 1, 24, 72, 48, 96, 120, 144, and 168 h at room temperature. Triplicate readings of each sample were carried out. Nickel results were based on the average concentration measure. The results for all the samples were blank corrected by subtracting the average value of the three corresponding blanks. The amount of nickel released per area unit was calculated and was expressed in µg/cm2.

Metal analysis

Chemical analysis of nickel was performed with flame atomic absorption spectrometry in our laboratory. Standard solutions containing 0.1, 1, 10, 50, 100 and 500 µg/l in 1% HNO3 were used for calibration.

Coin handling criteria

Kuwaiti cupronickel coins of 20 fils, 50 fils and 100 fils denominations were kept immersed in the prepared artificial sweat solution in a clean 1-liter glass container for 30 min.
At the beginning of the test the nickel releasing coins were placed in container A.
Step (1): All the subjects (in the two groups) were asked to wet their hands with the artificial sweat solution once directly before handling the coins.
Step (2): Each subject was instructed to pick 60 coins (20 of each denomination of 100 fils, 50 fils and 20 fils) from the container marked (A) containing 120 coins of each denomination, transfer them one by one to another empty container marked (B) in 5 min. These steps were repeated every 5 min for 30 min. At the end of the 30 min, all the coins in bowl (A) were transferred to bowl (B).
Step (2) was carried out 2 times a day for 7 days, 9 h apart (at 9 am and 6 pm).
Step (3): The same procedure was repeated after 3 months for both groups with non-nickel release coins. The subjects were followed for 3 weeks after handling the coins (2 visits every week) for recording the results. We did not do DMG test of the patients’ hands following the study.

Clinical scoring for signs of dermatitis [18]

Erythema: was graded from 0 to 5; 0 = no reaction; 1 = weak spotty or diffuse erythema; 2 = weak but well-perceptible erythema covering the total exposure area; 3 = moderate erythema; 4 = severe erythema with edema or palpable infiltration; 5 = very severe erythema with epidermal defects (vesicles, erosions, pustules or bulla formation).
Vesicles: The number of vesicles (including intact and more advanced broken vesicles) on the exposed areas was recorded on a semi-quantitative scale and was graded from 0 to 6 (0 = no vesicles; 1 = 1–10 vesicles; 2 = 11–20 vesicles; 3 = 21–30 vesicles; 4 = 31–40 vesicles; 5 = 41–50 vesicles; 6 = > 50 vesicles).
The individual vesicles were counted under a magnifying lamp. Scaling: was recorded as existent (1) or not existent (0). Itching: Graded as 0 = no itching, 1 = mild itching, 2 = moderate itching, 3 = severe itching.

Statistical analysis

The computer program SPSS (Chicago, IL, USA) was utilized for the statistical analysis. The Wilcoxon signed rank test or the Mann-Whitney rank sum test was performed for intra individual comparisons and between both the groups, respectively.

Results

Nickel release from Kuwaiti cupronickel coins

The amounts of nickel released from the coins in the artificial sweat solution at different intervals from 1 h to 168 h are depicted in Figure 1. Nickel was detected in all extracts, but the amount increased significantly with duration of immersion in the artificial sweat solution. The maximum amount of nickel released at 1 week was 35.15 µg/cm2/week from 100 fil coins and the minimum (28.64 µg/cm2/week) was from 20 fil coins.
Mean ± SD of age (years), sex and occupation distribution of patients finally analyzed in both groups are shown in Table 2.

Skin exposure to nickel by coin handling in both groups

Incidence of dermatitis in both groups after handling of nickel releasing coins is shown in Table 3. It showed that 52.7% of nickel sensitized patients (group I) did not develop any dermatitis during the study period. Thirty-three (36.3%) patients (7 males, 26 females) developed mild to moderate dermatitis, while 10 (11%) patients (4 males, 6 females) developed severe hand dermatitis during the observation period. In contrast, only 9 (10.4%) patients (4 males, 5 females) had mild to moderate and 3 (3.4%) patients (2 males, 1 females) from group II got severe dermatitis in the first phase of the study. A vast majority of 75 (86.5%) patients in group II did not develop any dermatitis after handling the nickel releasing coins. Out of these 9 patients with positive reactions, 2 (1 male, 1 female) showed nickel positive reaction on the repeat patch test.
Incidence of hand dermatitis dropped drastically in both groups after exposure to coated nickel coins (Tables 4 and 5). Six (6.66%) patients (2 males, 4 females) developed mild to moderate, whereas only 2 patients (1 male, 1 female) developed severe hand dermatitis among group I patients in the second phase of the study. Only 5 (5.7%) patients (2 males, 3 females) had dermatitis of mild to moderate severity after exposure to nickel coated coins among the group II subjects. No subject from group II had severe dermatitis.
Dermatitis in almost all the patients was noticed within 7 days of coin handling tests. The patients were given only systemic antihistamines to relieve pruritus, during all 7 days of coin handling. Thereafter, emollients and mid potency topical steroids were added. Systemic steroids for short duration were used in severe cases, and only after interpretation of results of repeat patch tests had been done.

Discussion

Nickel allergy

Nickel is one of the most common allergen causing contact dermatitis [19]. The prevalence of nickel allergy in the general population is estimated around 10%, and it still remains the most common cause of contact allergy worldwide. Females are affected more commonly (10%) compared to males (2%). Contact with jewelry and skin piercing are the probable contributory factors of this difference seen among females and males. Atopy increases the risk of nickel sensitization [20].
Common sources of nickel exposure to skin are jewelry, metal elements on clothing and apparels, belt buckles and wrist watches. Certain occupations also expose people to nickel at higher amounts, repeatedly and for prolonged duration thus posing a risk. These include nickel industry workers, electroplaters, electronic and general assemblers, saloon workers (beauticians, hairdressers), health care assistants, dental assistants, cooks and caterers [21].

Coin handling and nickel allergy

With the enactment of restrictive laws in most of the developed nations, the prevalence of nickel allergy has seen a downward trend especially in young females [7]. But, these laws still do not cover the causes of nickel allergy due to repetitive and short exposure to nickel for example as seen in coin handlers, like cashiers [8]. Hence, recently lot of attention has been paid to nickel releasing coins as a source of nickel allergy and dermatitis among certain occupations [22]. Nickel is used in making coins because the metal has excellent beneficial attributes such as low cost, shiny surface, sufficient weight, high corrosion resistance, recyclable and easy to stamp [23]. Coins of various denominations are used in almost all the countries for daily monetary transactions at various points of sales, trading and banking. Majority of the coins being used in most of the countries contain nickel or nickel alloys. In fact copper-nickel was the most frequently identified coin alloy (102; 28%) followed by aluminum–bronze (62; 17%). Amongst 361 denominations from 52 countries representing 75% of the world population, 239/835 (28%) released nickel. In some countries, more than one third of the denominations released nickel (US, Japan, Russia, Mexico). They released nickel at significant levels [24]. Cashiers and sales assistants comprise a special group of people, who may be exposed to large amounts of nickel from prolonged and repeated handling of metal coins because of the nature of their jobs. The role of handling coins in causing and aggravating dermatitis has been debated for long in the past [25]. According to Fisher [25], handling of coins in routine daily life causes insufficient exposure to skin so as to cause allergy and symptoms. A thick horny layer of the skin over palms may also protect. However, of late, consensus is emerging that handling of nickel releasing coins is a potential source of nickel sensitization and allergy [26].
The role of nickel exposure from coins as a contributor to causation or flare ups of signs and symptoms of nickel allergy and nickel hand dermatitis has also been questioned by the nickel coins producers, and some dermatologists. However, several elegant studies have demonstrated that nickel is released from the coins in significant amounts [27]. A significant amount of released nickel is thus deposited onto the skin, with small inter-individual variation, by handling of the coins in daily life. Therefore, coin handling is likely to play a role in nickel sensitization and dermatitis [28].

Nickel exposure and hand dermatitis

There are data to suggest that significant aggravation of hand dermatitis occurs, when patients with nickel allergy and ongoing mild to moderate hand dermatitis were exposed to nickel 10 min/day for 2 weeks [29]. The levels of nickel deposited may be sufficient to induce dermatitis in a significant number of nickel sensitized patients [30, 31]. The authors of these studies have concluded that nickel releasing coins pose a health hazard to nickel sensitized persons especially those engaged in occupations exposing them to repeated and prolonged contact with such coins. The amount of nickel released depends on the size, surface area, content and type of the coins. Accordingly, Nucera et al. [31] had concluded that new euro coins may be more dangerous than old Italian lira.
Julander et al. [14] in their recent study of newly introduced nickel-plated steel coins in the UK found that the amount of nickel deposited onto the skin during the handling of these coins for 1 h (7.5 µg/cm2) was four times higher than that from cupronickel coins. Initial nickel release rates were 10–27 times higher than 1-week rates, emphasizing that brief and repeated contact results in significant nickel exposure. They concluded that the nickel-plated coins deposit higher levels of nickel onto the skin than cupronickel coins, and hence pose an increased allergy risk. Furthermore, they suggested that 1-week nickel release in artificial sweat may not be suitable for determining the risk of handling items with high nickel release, and have recommended using nickel skin dose as a measure for risk assessment.

Kuwaiti currency coins and nickel content

Kuwaiti cupronickel coins of 100 fils, 50 fils and 20 fils denominations have been in circulation since 1961. Other alloy coins such as nickel brass (5 fils; 1961–2011), brass plated steel (5 fils; 2012), stainless steel (20 fils; 2001–2005) had also been in circulation. Nickel-plated steel coins of 100 fils denomination were introduced for 1 year in 2012 to 2013 [15]. The present study showed that nickel is released from Kuwaiti cupronickel coins of 100 fils, 50 fils and 20 fils denominations at high amounts during extraction with artificial sweat. The mean amount of nickel released from Kuwaiti cupronickel coins (100 fils, 50 fils and 20 fils), immersed in artificial sweat for 1 week was 35.15 µg/cm2, 32.76 µg/cm2, and 28.64 µg/cm2, respectively. While, the amount released from 2-euro coin was 99 µg/cm2/week [28]. The levels reported earlier were 23–65 µg/cm2/week [32] and 160 g/cm2/week [30]. Lower amounts of nickel released seen from Kuwait cupronickel coins may be because of smaller surface areas of Kuwaiti coins in comparison to 2-euro coin (2 euro is 12.2 cm2 and 100 Kuwaiti fils is 5.1 cm2).
The EU Nickel Directive states that items that will have direct and prolonged contact with the skin should not release more than 0.5 µg of nickel/cm2/week, and items for pierced holes not more than 0.2 µg/cm2/week. The amounts released from the cupronickel coins at 1-week are higher than this recommended level. Thus, repeated exposure to even low amounts of nickel, as occurs while handling coins may in fact considerably increase the risk of sensitization and elicitation of dermatitis [8]. This becomes more relevant with recent REACH definition of “prolonged skin contact” with nickel as 10 min on three or more occasions within two weeks or 30 min on one or more occasions within 2 weeks.
The role played by nickel containing coins in causing dermatitis in some patients is clearly brought about in the case report of a nickel-allergic bank clerk who counted coins for half of the workday suffering from dermatitis on the fingers, and later the hands. Vacations and changed work tasks resulted in complete healing. The investigators believed that the patient had been sensitized by coin handling, as she had never reacted to jewelry or other metallic items [21]. In another report, 2 nickel-allergic patients were presented: one developed dermatitis on the nose and the finger from rubbing a coin against the nose when it itched; the other one developed dermatitis on the finger, because he often carried a coin in the finger portion of the glove [25].
It is likely that dermatitis caused by coins is more common outside of Europe, because of the increased risk of sensitization in absence of stricter nickel regulations in day-to-day use items. The accumulation of case reports of nickel dermatitis from coins indicates that excessive cutaneous exposure to coins, as seen in cashiers and other occupational groups handling money, may result in nickel sensitization and dermatitis [22, 26]. However, there are some reports to the contrary, where the authors have not found a positive correlation to exposure to nickel coins and occurrence of nickel allergy and dermatitis. Christensen and Moller [33] reported that intense handling of nickel-containing metal objects by patients with nickel contact allergy did not induce visible eczematous activity. Similarly, Zhai et al. [18], in a cross-over design study on 18 subjects (10 nickel sensitized and 8 non nickel sensitized) exposed to nickel containing and nickel coated coins, did not find anyone developing allergic contact dermatitis to nickel containing coins. The subjects were asked to handle 10 coins for 5 min followed by 5 min of rest for 8 h a day for 12 days in a cross-over design study. Meding and Swanbeck [34] found no significant increase in prevalence of hand eczema in individuals. On the other hand, several cases of nickel coin dermatitis have been reported [8, 18, 22, 26, 35]. Pressure can be an additional contributory factor in nickel dermatitis in sensitized persons [8]. When nickel coins were kept on the palms under occlusion for 24 h, allergic contact dermatitis occurred in nickel-sensitive persons [25].
Nickel skin bioavailability depends on the type of the nickel compound or alloy, vehicle, potential occlusion, skin site and degree of skin inflammation. In particular, a compromised skin barrier may facilitate penetration of nickel and hence greatly increase reactivity [36]. In addition, the amount of nickel released from nickel alloys is a critical factor for nickel dermatitis [37]. Emmett et al. [38] found that the lowest patch test elicitation threshold in a statistically significant number of nickel-sensitive individuals was 1.5 µg per patch test. Highly sensitized individuals might react to 0.47 µg/cm2 when exposed to inflamed skin under occlusion [38].
In a newly developed ‘finger immersion method’ to study the amount of nickel deposited in nickel exposed individuals, Staton et al. [29] contended that 2 µg/cm2 of nickel may represent ‘normal’ skin levels. They also found that coin handling induced an appreciable increase in the amount of nickel on the skin within 2 min. Their experiments indicated a linear relationship between coin handling (exposure time) and measured dermal nickel levels following standardized coin handling. A pilot survey, conducted among cashiers, shop assistants, bar staff, hairdressers and workers in the nickel industry revealed dermal nickel concentrations ranging from < 0.9 to 7160 ng/cm2. They found the method to be superior, compared to the acid wipe test and tape stripping in terms of extraction efficiency, speed and ease of operation in the field.
Gawkrodger et al. [39] used the same method to measure the quantities of nickel on the skin of the fingers in workers employed in occupations for which nickel has been suspected as a contact allergen, and to define the threshold for a dermatitis reaction after the single application of a quantity of nickel to the skin of nickel-allergic individuals when read at 2 days. They found that nickel levels on the fingers of electroplaters, cashiers, sales assistants, caterers, and even office staff, were at or above 0.035 µg/cm2. At these levels, 22% of nickel-allergic subjects will react. This single open application of nickel study demonstrated a dose-response relationship, with no subjects reacting to ≤ 2.5 µg/cm2, but increasing numbers reacting at higher concentrations as follows: 6 of 21 (28%) at 5.0 µg/cm2, 6 of 19 (31%) at 15 µg/cm2, 7 of 19 (37%) at 30 µg/cm2 and 11 of 18 (61%) at 45 µg/cm2. The authors concluded that nickel levels on the skin in coin handling occupations and some others are sufficient to induce an allergic contact dermatitis in some nickel-allergic subjects. A single application of 5 µg/cm2 when read at 2 days, induced a dermatitis reaction in 6 of 21 nickel-allergic subjects [39].
In our study we found that brief but frequently repeated contact with nickel releasing coins resulted in hand dermatitis in both nickel-allergic (43/91; 47.3%) group I patients and nickel non-allergic subjects (12/87; 13.8%). However, in one controlled provocative use test study with nickel-containing coins (Canadian 5 cent coins, Cu 75% and Ni 25%) and nickel-coated coins (Canadian 1 cent coins, Cu 98% and Zn 2% or Cu-plated Zn), 18 subjects (10 nickel sensitized and 8 non-nickel sensitized) handled 10 coins (nickel containing coins or nickel-coated coins) in a crossover design at 5 min intervals for 8 h per day, for a total of 12 days. The authors found that the subjects handling nickel-containing coins daily did not develop allergic contact dermatitis [40]. This can be debated by discussing the following point when interpreting the results: the subjects had normal skin, one hand was protected by a thick cotton glove during coin handling, hands were placed through a heavy fabric hood to prevent coin exposure, and only 10 coins were handled by each subject during 12 days [41]. In our study, only 8 out of 91 (8.8%) in group I and just 5 (5.7%) out of 87 of group II developed dermatitis on exposure to nickel non-releasing coins. This could be due to irritation rather than allergic reasons due to repeated exposure to artificial sweat and friction.
Regulations in Europe reducing the permissible amount of nickel release from jewelry and other items have significantly reduced the prevalence of nickel allergy and nickel dermatitis [17, 42, 43]. Similar measures have been advocated in regards to nickel containing coins. Some authors have recommended the use of non-nickel coins to minimize the risk of exposure to nickel, with the aim to reduce the incidence of nickel sensitization and nickel dermatitis [14, 22, 30, 31].

Conclusions

Nickel is released from Kuwaiti coins of 100 fils, 50 fils and 20 fils denominations in significant amounts. Hand dermatitis was developed in a considerably greater number of nickel sensitized patients compared to nickel non-sensitized patients on controlled exposure to these nickel releasing coins. Handling of nickel releasing coins may induce or flare up dermatitis in people exposed repeatedly or for prolonged duration because of the nature of their jobs. Such coins may also induce nickel sensitization among the general population. We support the recommendation that non-nickel releasing coins made of other metal alloys be used for manufacturing coins to minimize the risk of sensitization and dermatitis from nickel.

Acknowledgments

This work was financially supported by a grant from the Kuwait University (MM013). Source of funding: KU Grant MM013.

Conflict of interest

The authors declare no conflict of interest.

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