A Compilation of Metals and Trace Elements Extracted from Materials Relevant to Pharmaceutical Applications such as Packaging Systems and Devices

Results and Discussion

Thirty-two elements—Ag, Al, As, B, Ba, Be, Bi, Ca, Cd, Co, Cr, Cu, Fe, Ge, Li, Mg, Mn, Mo, Na, Ni, P, Pb, S, Sb, Se, Si, Sn, Sr, Ti, V, Zn, and Zr—were targeted for quantitation for several reasons, including

1. Potential safety impact

2. Potential product impact

3. Probability of being present based on test article composition

The reporting thresholds for the extracted amounts of the targeted analytes were generally 0.05 μg/mL for all elements except a few (e.g., Ge and Li) that had a reporting threshold of 0.10 μg/mL. This difference occurs because the absolute value of the reporting threshold is determined at each test interval and there is some interval-to-interval, as well as element-to element, variation in method performance. The reporting threshold is not necessarily the method's limit of quantitation but reflects that concentration at which one can reliably discern a difference between the level of an analyte in an extract and its level in an associated extraction blank. This distinction between a practical and differential quantitation limit (QL) versus an absolute QL is relevant, as the amount of the analyte extracted from a test article is the difference between two measurements (amounts of the analyte in the extract and in the extraction blank) and not the result of a single measurement. This situation is illustrated via the following example. In this example, the test method has a QL of 0.01 μg/mL; at this QL the accuracy is 100 ± 50% and the precision is percent relative standard deviation (%RSD) = 25%. An extract and an extraction blank are tested, and the test results are extract = 0.04 μg/mL extraction blank = 0.02 μg/mL. Both the measurements are above the QL, and the difference (0.02 μg/mL) is also above the QL. However, one cannot claim, with confidence, that the extracted concentration is 0.02 μg/mL because the uncertainty in the individual results is greater than their difference.

The extraction stoichiometry (extracted material weight per unit volume of extracting solution) varied somewhat for each material tested because the intent of the testing was to establish each material's extractables properties under conditions similar to its clinical use. Thus materials that are used in different clinical settings were extracted in a different manner. Nevertheless, a stoichiometry of 1 g of material per 10 mL of extraction solvent was most commonly used. In this circumstance, the reporting threshold of 0.05 μg/mL on a solution basis corresponds to a reporting threshold of 0.5 μg/g on a material basis. Values less than the reporting threshold are contained in this paper but are considered to be concentration estimates that most correctly indicate that the particular element was detectable as an extractable in a particular circumstance.

The extracted metals and trace elements results are grouped in terms of the tested material type and are summarized in Tables IV through XVI. In general, the 32 targeted elements can be classified into four groups as a function of how frequently they were present in the extracts in reportable quantities. Thirteen of the targeted elements, Ag, As, Be, Cd, Co, Ge, Li, Mo, Ni, Sn, Ti, V, and Zr, were not extracted from any of the tested materials in measurable quantities. Eight other targeted elements, Bi, Cu, Cr, Mn, Pb, Sb, Se, and Sr, were rarely extracted in measurable quantities and were sporadically present in only a few extracts at levels near the reporting thresholds. Three additional elements, Ba, Fe, and P, were infrequently extracted in measurable quantities, meaning that while they were more prevalent than the sporadic elements, they were still present in less than 5% of all the tested extracts. These elements were generally extracted from certain types of test materials and not universally extracted from many different types of materials. Thus Ba was generally extracted from glass, PP, and acrylic copolymer; Fe was generally extracted from stainless steel; and P was generally extracted from materials, such as PP, silicone, and thermoplastic elastomers, that typically include phosphite-based anti-oxidants.

The remaining eight elements, Al, B, Ca, Mg, Na, S, Si, and Zn, were those elements that were most commonly extracted in measurable quantities. None of these elements were extracted in measurable quantities from all the individual materials in each material group. The most prevalent extracted elements were Si and Na, which were extracted from individual materials across almost all the material groups but not all the individual materials within each group. Silicon was extracted in several materials, such as glass and silicone rubber, at concentrations well above 1 μg/mL and in many other individual materials in lesser amounts. The levels of extracted silicon exhibited two trends as function of the extraction solvent. For certain material groups, most notably acrylonitrile butadiene styrene (ABS), glass, rubber elastomer, and acrylic copolymers, the levels of extracted silicon were highest in the high pH extracts, which is consistent with an inorganic source of the silicon. For other material groups, most notably polymethylmethacrylate acrylic (PMMA) and silicone rubber, the levels of extracted silicon are highest in the ethanol/water extracts, consistent with an organic source of the silicon. Sodium was extracted in varying amount from many of the individual materials in all the material groups. Considering the other, less frequently encountered elements, zinc was generally extracted from the poly-vinyl chloride (PVC) and rubber elastomer materials in relatively higher amounts and only sporadically at much lower amounts from other individual materials. Sulfur was generally extracted from the rubber elastomers at relatively higher levels, from certain PP materials at much lower levels, and sporadically at lower levels in individual materials in the other groups. Calcium was extracted from many individual PVC, glass, PP, silicone, and rubber elastomer materials and more sporadically from materials in the other groups. Magnesium was primarily extracted from PVC and ABS materials; aluminum was more commonly extracted from the glass, PP, and rubber elastomer materials; and boron was most commonly extracted from the PVC, PP, silicone, and rubber elastomer materials.

Given the diversity of the test materials and the extraction conditions, it is difficult to elucidate universal trends in the extractables data. Nevertheless, two trends relating the concentration of certain extractables and the conditions of extraction, specifically extracting solution composition, could be discerned in the data. For example, the amounts of extractable metals and alkaline earths were generally higher in the low pH extracts, suggesting that ion exchange is an important extraction mechanism for these extractables. Additionally, the levels of extracted sulfur were generally higher in the pH 9 extracts, suggesting that one or more test article additives contained acidic sulfur moieties.

One way to utilize the results summarized in this article is to compare the test results with existing and/or developing requirements or recommendations for the composition of plastic materials used in pharmaceutical applications. Thus, for example, monographs for individual plastic materials that appear in the European Pharmacopeia (Ph. Eur.) prescribe the extraction of the materials and testing of the extracts for specified elements (14). As the extraction methods used to characterize the materials reported in this manuscript differ significantly from those in the Ph. Eur. (for example, the Ph. Eur. tests typically involve a high temperature, reflux-type of extraction with an acidic medium), it is not appropriate to rigorously compare the concentration results reported herein versus the Ph. Eur. elemental limits. However, one can qualitatively compare the list of Ph. Eur.–specified metals with those which were, or were not, detectable in the materials summarized in this paper. For instance, the various Ph. Eur. monographs on PVC materials used in a variety of applications target Ba, Cd, Ca, Sn, and Zn. Of these five targets, only Ca and Zn were present in detectable quantities in the PVC materials reported here. Similarly, the Ph. Eur. monograph for polyethylene terephthalate (PET) targets Al, Sb, Ba, Co, Ge, Mn, Ti, and Zn, none of which were extracted in reportable quantities from the PET materials reported herein. Considering polyethylene (PE) materials, the relevant Ph. Eur. monographs target Al, Cr, Ti, V, Zn, Zr, none of which were extracted in reportable quantities from the PE materials reported herein. Lastly, the Ph. Eur. monograph for PP targets Al, Cr, Ti, V, and Zn; of these targets, only Al and Zn were extracted in reportable quantities from the PP materials reported herein.

Similarly, one can compare the extractable elements data summarized herein to requirements and/or specifications for elemental or metallic impurities in drug products. Such a comparison is relevant because materials used in packaging are a potential source of elemental impurities in drug products. While a quantitative comparison between the results summarized in this paper and the specifications or limits for individual elemental impurities is not appropriate because the extractions performed on the materials that are contained in this study were not designed to facilitate such a quantitative comparison, one can qualitatively compare those elements that have limits or specifications with those that were extracted in reportable levels for the materials contained in this paper. For example, EMEA/CHMP/SWP/4446/2000, Guideline on the Specification Limits for Residues of Metal Catalysts or Metal Reagents (15), classifies 14 metal residues in terms of their safety concern and contains concentration limits for those residues, including Pt, Pd, Ir, Rh, Ru, Os, Mo, Ni, Cr, and V as metals of significant safety concern, Cu and Mn as metals with low safety concern, and Fe and Zn as metals with minimal safety concern. Of these 14 specified metals, Pt, Pd, Ir, Rh, Ru and Os were not targeted in the analyses reported herein and thus no comparison can be made. However, it is noted that three of the four remaining metals of significant safety concern, Mo, Ni, and V, were not extracted in reportable quantities from any of the materials contained in this study. The fourth remaining metal of significant safety concern, Cr, was rarely extracted from the materials in reportable quantities, and when it was extracted at reportable levels, the levels were typically low, less than 1 μg/g. Both metals with low safety concern, Cu and Mn, were rarely extracted from the materials included in this study in reportable quantities, and when the extracted amounts were reportable they were low, typically less than 0.1 μg/g. Considering the two metals of minimal safety concern, Fe was infrequently extracted from the materials in reportable levels. On the other hand, the remaining metal of interest, Zn, was one of the more commonly encountered extractable metals and was extracted from certain materials (for example, certain rubber elastomers) in quantities significantly higher than 1 μg/mL.

A similar appraisal can be made between the results reported in this study and the elemental impurities in pharmaceuticals that are listed in USP General Chapter <232> Elemental Imputrities—Limits (16). Those elemental impurities that appear in both the USP general chapter and the EMEA guideline are discussed in the preceding paragraph. Elements unique to USP General Chapter <232> include As, Cd, Hg, and Pb. Considering these elements specifically, Hg was not targeted in the analyses reported in this article and thus no comparison can be made. Both As and Cd were not extracted from any of the materials reported in this article in reportable quantities. While Pb was reported as being rarely extracted from the materials reported in this study (and at low levels when it was extracted), the occurrences of reportable extracted lead were limited to lead glass materials.

The essence of this comparative discussion is captured and summarized in Table XVII.

In the final analysis, information such as that summarized in this paper may be useful in establishing requirements related to the presence of extractable elemental impurities in manufacturing systems, packaging systems, medical devices, and their associated materials of construction. Effective, achievable, and practical requirements are obtained by balancing the objectives of such requirements (e.g., producing safe and effective pharmaceuticals) with full knowledge of the types, levels, and frequencies of extractable elemental impurities that exist in packaging systems, devices, and their associated materials of construction.