Reaction products of sodium glucoheptonate with copper sulfate and ammonium hydroxide

There are several case reports concerning copper sensitivity in humans (for a review see Forstrom et al. 1977), but the incidence has not been documented. In order to attempt to elucidate this question, copper sulfate has been included in a routine patch test series (Wahlberg, unpublished). Two groups of 20 animals were used. One group was actively sensitized and the other group (control) was treated in the same way as the experimental group (Freund's complete adjuvant, petrolatum occlusion, etc.) except for the test compound. Concentrations for induction were 0.01 % (intradermal) and 25 % (epicutaneous). The animals were challenged by 0.1, 0.5 and 1.0 % CuSO4 x 5 H2O in petrolatum). Statistical method was the chi-square test (two-way tables).

At the challenge concentration 1%, two (24 h) and seven (48 h) animals reacted compared to none (24 & 48 h) among the controls. The difference was statistically significant at the 48-h reading.

In an Assay for evaluating expression of matrix metalloproteinases in experimental wound healing model, wound chambers were inserted under the skin of Sprague-Dawley rats and received serial injections of either 2 mg glycyl-L-histidyl-L-lysine-Cu(II) or the same volume of saline. The wound fluid and the neosynthetized connective tissue deposited in the chambers were collected and analyzed for matrix metalloproteinase expression and/or activity. Copper tripeptide increased expression/activity of the following enzymes: interstitial collagenase, matrix metalloproteinase-9 (gelatinase B), matrix metalloproteinase-2 (gelatinase A), and pro-matrix metalloproteinase-2. Copper tripeptide-1 also increased cell invasion and extracellular matrix deposition in chambers.

In an in vitro test, the effect of copper tripeptide on normal and keloid-producing dermal fibroblasts in a serum-free in vitro model was evaluated. The cellular response was described in terms of viability and secretion of basic fibroblast growth factor (bFGF) and transforming growth factor-β1 (TGF-β1). Primary cell lines were established from patient facial skin samples obtained during surgery and plated in serum-free media. At 0 hour, copper tripeptide (1x10E-9 mol/L), or appropriate control vehicle was added. Cell counts and viability were established at 24, 72, and 120 hours. Supernatants were collected at the same intervals and were assessed for bFGF and TGF-β1 concentrations using the enzyme-linked immunosorbent assay technique.

Cell lines showed viability between 86% and 96% (mean, 92%) throughout the experiment. Normal and keloid-producing dermal fibroblasts treated with copper tripeptide secreted less TGF-β1 than did controls, suggesting a possible clinical use for decreasing excessive scar formation.

"The Panel acknowledged that sucrose and glucose are used in cosmetics at relatively high concentrations, and that data from irritation and sensitization studies at maximum use concentrations of these ingredients are lacking; however, based on the clinical experience of the Panel, there is little concern that these ingredients are irritants or sensitizers".

No published studies are available which report on the potential of copper or its compounds to cause skin sensitisation in animals.  

Several unpublished studies have been made available, using the guinea pig maximisation test of Magnusson and Kligman or the Buehler test and all have been conducted according to EU Annex V or OECD guidelines.  These studies have investigated the skin sensitising potential of copper (I) oxide, copper (II) oxide, copper sulphate pentahydrate, copper oxychloride and copper powder. In these tests, none of the substances investigated have demonstrated potential to cause skin sensitisation in guinea pigs.

There have been several reports in humans of skin reactions to copper either as the metal, principally from jewellery and intra-uterine devices (IUDs), or in copper salts, principally from the use of copper sulphate as a pesticide. Positive reactions from patch tests have been reported following challenge with 1-5% solutions of copper sulphate and, in a single case, with copper oxide. The possibility of cross-reactivity to salts of potent sensitisers exists. The prevalence of sensitisation to copper sulphate among patients with pre-existing skin conditions are reported to be of the order of 1% but is unknown among asymptomatic individuals. The largest investigation of women using copper containing IUDs (n=37) who reported side effects including skin reactions (n=10) found that none reacted positively to copper in patch tests. This finding suggests that copper was not responsible for their symptoms.

The following clinical criteria should be satisfied to accept a reported case of skin sensitisation as likely to be caused by copper or its compounds:

- a clear history of significant dermal exposure to the copper species, followed by

- experience of skin rashes, and

- a positive reaction on patch testing

Using the above criteria resulted in very few documented cases of copper and/or its compounds as a cause of skin sensitisation in humans in the medical and scientific literature. Given the extensive use of copper, and the potential for continuous and/or intermittent skin contact, human case-reports of skin sensitisation due to copper or its compounds are rare.

No information is available from animal or human studies concerning the potential of copper substances covered by this Risk Assessment to cause respiratory sensitisation. In the absence of any relevant data, the potential to cause respiratory sensitisation cannot be assessed. 

Classification for sensitisation

Current classification of copper (I) oxide, copper (II) oxide, copper sulphate, copper oxychloride and copper powder for sensitisation: none

Available animal and human data on the skin sensitisation properties of copper (I) oxide, copper (II) oxide, copper carbonate, copper sulphate, copper oxychloride and copper powder have been considered against EU classification criteria as contained in Annex VI of Directive 67/548/EEC.  The available animal data do not meet the criteria requiring these substances to be classified for skin sensitisation. Human data on skin sensitisation properties of copper or its compounds are insufficient to require classification for skin sensitisation.

With regard to sensitisation by inhalation, in the absence of relevant human or animal data, there is no basis for classification of copper substances covered by this Risk Assessment for respiratory sensitisation.

Data to be carried forward to ‘Risk Characterisation’:

Available data provide no evidence that copper (I) oxide, copper (II) oxide, copper oxychloride, copper sulphate or copper powder cause skin sensitisation. Consequently, no data on skin sensitisation are carried forward to ‘Risk Characterisation’. 

In the absence of data on the potential of copper or copper compounds to cause respiratory sensitisation in animals or humans, no data on respiratory sensitisation are to be carried forward to ‘Risk Characterisation’.

In a dermal sensitization study with Copper sulphate pentahydrate in 20% ethanol solution, 6-8 week old female Balb/c mice (three animals / dose) were tested in the murine local lymph node assay. The test substance was applied on three consecutive days on the dorsum of each ear, local lymph nodes were isolated on fourth day after application. Isolated cells were cultivated with [3H]methyl thymidine ([3H]TdR) and [3H]TdR incorporation was measured with a scintillation counter.

The stimulation index (SI) was determined to be 2.67. In this study, Copper sulphate pentahydrate is considered to be a dermal sensitizer.

Routine human patch testing with 2% copper sulphate did not reveal any conclusive case of contact sensitivity. Several concomitant reactions, especially to cobalt, nickel, and eliminate were seen in the 13 patients and the results of the serial dilution tests did not support the existence of a true sensitivity to copper. Serial dilution tests with nickel and cobalt demonstrated that impurities of the metals are possible explanations for some of the initial test reactions.

The guinea pig maximization tests explicitly demonstrated that copper sulphate is a grade 1 allergen according to the classification of Magnusson & Kligman. No difference between copper-exposed and control animals was observed in any of the 3 test series

126 enamellers and 64 decorators from 5 factories underwent dermaiological and allergological examination using occupational test series in order to evaluate the prevalence of dermatitis and contact sensitization, and to identify the most important sensitizing substances. 44 workers (corresponding to 25.26% of the study population) were sensitized, with a total of 55 positive patch tests. Dermatitis was present in 22 workers, whereas 44 subjects claimed to have had skin lesions in the past. We found 17 positivities to specific substances: 7 to red iron oxide; 2 to antimony trioxide, manganese dioxide and maleic anhydride; and 1 to red copper oxide, cadmium chloride, vanadium pentoxide and sodium tripolyphosphate.

Copper is frequently employed in industry and has always been regarded as a weakly sensitizing metal. As previously mentioned, we only found 1 case (among enamellers only) of sensitization.

There are only few reports of sensitisation to copper with an immunological aetiology. Most of the documented cases were regarded as either unspecific or cross reactions to nickel allergy (ATSDR 2004, Greim 2004). With regard to the extensive use of copper and its compounds and the small number of case reports, there is little concern about the sensitising properties of copper.

Human data

Copper and copper sulphate may evoke allergic contact dermatitis. Testing of patients with contact eczema or of workers occupationally exposed to copper dust or fumes provoked dermal reactions following testing with copper sulphate in concentrations up to 5 % copper sulphate. However, the number of reported cases with a clear copper induced sensitisation is very low and was observed only at high concentrations of 5 % of copper salts (Walton et al 1983a, b). The observed dermal reactions were mostly either unspecific or cross reactions to a nickel allergy. In some cases, they may have been provoked by nickel contaminations of the copper (Greim 2004). A single case of occupational respiratory sensitisation is reported. A worker in the galvanic industry showed a 30 % decline of the forced expiratory volume after provocation with 1 mg copper sulphate/m3 (Cirla 1985).

Animal data

Two maximisation tests in guinea pigs with the pentahydrate of copper sulphate in petrolatum yielded conflicting results (Boman et al 1979, Karlberg et al 1983). As these studies were done by the same working group at similar conditions, the reason for this discrepancy is unknown. One Local Lymph Node Assay (LLNA) in mice with 10 % copper sulphate pentahydrate in ethanol failed to show a positive reaction (Ikarashi et al 1992). Another LLNA with copper chloride (1–5 % in DMSO) exhibited a strong lymphocytic proliferation, but this was attributed to the local necrotic action of the compound (Basketter et al 1999).

The main purpose of this investigation was to estimate the incidence of copper sensitivity in patients with eczema attending 4 Dermatology Departments in ihe Northern Region of England over a 5-month period. Copper sulphate (as 5 % in petrolatum) was used in the patch test with AI test strip and a porous tape. When positive tests were encountered, patch tests were repeated after an interval, using 0.25%, 0.5% and 1 % (pet.) copper sulphate. Reproducibility was confirmed with readings both at 48 and 96 h.

354 patients were studied: 6 patients gave a positive reaction to copper sulphate and 39 to nickel sulphate; all patients reacting to copper sulphate were also nickel sensitive. All the patients reacting to copper were females with hand eczema, but none were employed in an occupation in which copper was encountered, and none wore an intra-uterine copper contraceptive device. Atopy was excluded in ihe positive patients by a negative personal and family history and negative reactivity on prick testing with house dust mite, grass pollen and animal furs. All 6 patients developed a positive eczematous response to 0.25%, 0.5%, 1% and 5 % concern rations of copper sulphate. The control site using the vehicle alone was negative.

Copper is used mainly in the electrical industry and for pipes conveying water or gas. It is also an important constituent of coins and printing plates. In spite of its widespread uses, its sensitising potential is extremely low.

The high incidence of hand eczema among this group and the lack of occupational exposure to copper suggest that nickel- and copper-containing coins may be a potential source of sensitivity. This study lends support to the clinical experience of most dermatologists, that allergic sensitivity to copper is rare. We suggest that nickel-sensitive patients who do not respond to nickel withdrawal should be patch tested to copper. Finally, we carried out further patch tests using concentrations of 10 % copper sulphate and above. Such concentrations resulted in some primary irritant reactions in patients with active eczema and we feel that it is not useful to test with a concentration higher than 5%.