Abstract
Since 1991, the skin bank of the Queen Astrid Military Hospital uses food-grade aluminum foil as a primary support for storing cryo preserved human donor skin (511 donors). The possible release of heavy metals into the cryo preservation media (30% (v/v) glycerol in physiological water) and the possible impact this release could have on the quality of the cryo preserved donor skin was evaluated. Aluminum was the principal detection target. Possible contaminants of the aluminum foil as such (arsenic, cadmium, chromium and lead) were also investigated. The evaluation was set up after a Belgian Competent Authority inspection remark. Aluminum was detected at a concentration of 1.4 mg/l, arsenic and lead were not detected, while cadmium and chromium were detected in trace element quantities. An histological analysis revealed no differences between cryo preserved and fresh donor skin. No adverse reactions in patients, related to the presence of aluminum or heavy metal traces, were reported since the introduction of the cryo preserved donor skin in our burn wound centre.
Keywords: Skin banking, Cryo preservation, Metal release, Food-grade packaging material, Aluminum
Introduction and rationale
The intertwined quality and safety issues are essential in all medical activities. Also in the fast growing field of tissue and cell banking there is an increased awareness.
The skin bank of the Queen Astrid Military Hospital uses food-grade aluminum foil (Alcomet, Aluminum foil 8011A) as a primary support for storing cryo preserved human donor skin. This procedure is in use in our skin bank since 1991. We process about 65 skin donors each year. This quantity covers the need of the Brussels burn wound centre. The storage time in our skin bank ranges in practice from 1 month to 1 year. Since the beginning of our activities, cryo donor skin retain samples were taken and stored for future use in safety and quality related tests.
Tissue banking is a field in which an intensive and worldwide growth and exchange is emerging. In order to safeguard quality and safety, controlled and validated standard operating procedures are needed. A recent inspection by the Belgian Competent Authority raised the question whether ‘food-grade’ aluminum foil is suitable for use in our donor skin cryo preservation procedure. To be more specific, we were asked whether the possible release of aluminum and/or heavy metal contaminants from the food-grade aluminum foil into the cryo preservation medium could have a negative impact on the quality of the cryo preserved donor skin and subsequently on the recipient patient.
With this short communication we try to answer this pertinent question in a pragmatic way.
Aluminum was the principal targeted analyte, but some relevant heavy metal contaminants like arsenic (As), cadmium (Cd), chromium (Cr) and lead (Pb) were also taken into account, because they are known to be present, in trace element quantities, in the considered aluminum foils.
To investigate this issue we proceeded as follows. First, a quantitative analysis of the above mentioned metals in skin cryo preservation medium, retrieved from stored retain samples, was performed. Second, a histological analysis of the stored cryo preserved donor skin was performed in comparison to fresh human skin. Third, we questioned burn surgeons, who had used our cryo preserved skin on their patients since 1991, about any aluminum or heavy metal related adverse (clinical) reactions.
Materials and methods
Donor skin packaging
Donor skin (Fig. 1) is impregnated, for 30 min, in cryo preservation medium (30% (v/v) glycerol in physiological water) and transferred to a food-grade aluminum foil support (Fig. 2). The donor skin is in direct contact with the aluminum foil support.
Fig. 1.
Fresh donor skin impregnation in cryo medium
Fig. 2.
Donor skin on food-grade aluminum foil support
Each aluminum foil support holds approximately 300 cm2 of donor skin. After addition of an extra 5 ml of cryo preservation medium, each aluminum foil support is folded and seal-packed in a Class IIa laminated aluminum pouch (Fig. 3), which provides for an extra mechanical protection during the long-term storage of the skin grafts (Fig. 4) in the vapor phase of liquid nitrogen (<−135°C).
Fig. 3.
Donor skin seal-packed in double pouch
Fig. 4.
Donor skin stored in vapor phase of liquid nitrogen
Quantitative detection of metal contaminants
Set up 1
Metal contaminants (Al, As, Cd, Cr, Pb) were quantitatively measured in the individual cryo preservation media from 10 donor skin retain samples (10 donors), with storage times ranging from 20 h to 10 years, using graphite furnace atomic absorption spectrometry (GFAAS).
Set up 2
Aluminum was quantitatively measured in the pooled cryo preservation medium from seven donor skin retain samples (7 donors), with a storage time of 10 years, using inductively coupled plasma atomic emission spectrometry (ICP-AES).
Cryo preservation medium that had not been in contact with food-grade aluminum foil and did not have contact with cryo preserved donor skin either was used as a control sample in both set ups.
Histological analysis
The retain skin samples from set up 1 (see section above) were fixated in formol at 10% and sent to the pathological anatomy service for histological analysis. Two stains were carried out; a classical haematoxylin eosin staining for the evaluation of the general cellular structure followed by a periodic acid Shiff reaction (PAS), which allows a thorough evaluation of the skin basal membrane.
An experienced dermato-pathologist performed a blind microscopic evaluation of the structural integrity of the skin retain samples in comparison to fresh skin samples. This evaluation was based on the pigmentation, presence and integrity of hair follicles and their associated muscles, sweat and sebaceous glands, and the dermal-epidermal junction. The skin samples were also screened for the presence of apoptotic and/or necrotic cells, sentinels of local tissue stress and inflammation.
Clinical evaluation
Burn surgeons (16), who had used our donor skin during the past 15 years, were contacted and questioned by the actual Medical Director of the Skin Bank about any aluminum or heavy metal related adverse (clinical) reactions, using a standardized questionnaire. Allergic reactions, intoxications, irritations, other?
Results
Chemical analysis
The GFAAS measurements of Al, As, Cd, Cr, Pb in the cryo preservation media of 10 donor skin retain samples are shown in Table 1. Al, As and Pb were not detected (below detection limit), while Cd and Cr were detected in trace element quantities (ppm, mg/l).
Table 1.
Aluminum and other metal concentrations in skin cryo preservation medium retain samples
| Donor ref. | Contact time | Aluminum (Al) | Arsenic (As) | Cadmium (Cd) | Chromium (Cr) | Lead (Pb) |
|---|---|---|---|---|---|---|
| GFAAS technology (mg/l) | ||||||
| BSB-08 067 | 21.5 h | bdla | bdl | bdl | bdl | bdl |
| BSB-08 068 | 3 Days | bdl | bdl | bdl | 0.0016 | bdl |
| BSB-08 053 | 15 Weeks | bdl | bdl | bdl | 0.0111 | bdl |
| BSB-08 056 | 14 Weeks | bdl | bdl | bdl | 0.0029 | bdl |
| BSB-08 062 | 10 Weeks | bdl | bdl | bdl | bdl | bdl |
| BSB-98 001 | 10 Years | bdl | bdl | bdl | 0.0242 | bdl |
| BSB-98 003 | 10 Years | bdl | bdl | 0.0045 | 0.0218 | bdl |
| BSB-98 004 | 10 Years | bdl | bdl | 0.001 | 0.0085 | bdl |
| BSB-98 007 | 10 Years | bdl | bdl | 0.003 | 0.018 | bdl |
| BSB-98 008 | 10 Years | bdl | bdl | 0.0045 | 0.0108 | bdl |
| BLANC | BLANC | bdl | bdl | bdl | 0.0042 | bdl |
| Detection limits | ppm (mg/l) | |||||
|---|---|---|---|---|---|---|
| Aluminum | 0.040–2000 | |||||
| Arsenic | 3–150 | |||||
| Cadmium | 0.02–3 | |||||
| Chromium | 0.06–15 | |||||
| Lead | 0.10–30 |
a bdl below detection limit
The ICP-AES measurements of Al in the pooled cryo preservation medium of seven donor skin retain samples, all dating from 10 years old, are shown in Table 2. Aluminum was detected at a concentration of 1.4 mg/l.
Table 2.
Aluminum concentration of the seven pooled skin cryo preservation medium retain samples
| Donor ref. | Contact time | Aluminum (Al) |
|---|---|---|
| ICP-AES technology (mg/l) | ||
| BSB-99 001 | 10 Years | 1.4 |
| BSB-99 003 | 10 Years | |
| BSB-99 004 | 10 Years | |
| BSB-99 005 | 10 Years | |
| BSB-99 006 | 10 Years | |
| BSB-99 007 | 10 Years | |
| BSB-99 010 | 10 Years | |
| BLANC | BLANC | bdla |
Detection limit Al: 100 μl/l
a bdl below detection limit
Histological analysis
The histological analysis revealed no differences between the cryo preserved donor skin retain samples and fresh skin (Fig. 5).
Fig. 5.
Donor skin section (200×, haematoxylin eosin staining and PAS reaction) after 10 years cryo storage
Hair follicles and sweat and sebaceous glands were clearly present and intact in the cryo preserved skin. The cryo preserved skin harbored no apoptotic or necrotic cells and showed a normal pigmentation and an intact dermal-epidermal junction.
Aluminum foil contact times (storage from 20 h to 10 years) had no impact on the results.
Clinical evaluation
No adverse reactions (e.g. hypersensitive reactions or signs of intoxication) related to the presence of aluminum or heavy metal traces in the grafts were reported.
Discussion
According to the European Medical Device Directive (MEDDEV), packaging materials for human cells and tissues for human application should be certified Class IIa Medical Devices. Specific human cells and tissues need specific (tailor made) packaging materials. For some specific applications, like the cryo preservation of skin, suitable Class IIa packaging materials are not available on the market.
In those cases regulatory bodies should accept the use of non-Class IIa (e.g. food-grade) products, pending the eventual development and commercialization of adequate Class IIa materials. A proper validation of the adequacy of these non-Class IIa materials in the specific application is, however, warranted.
The cryo preservation solution is removed by an obligatory procedural rinsing step before clinical use and is therefore only indicative for the level of absorption of aluminum and/or heavy metals in the tissue, which is in turn only indicative for the adsorptions of these contaminants in the recipient patient. The final absorption levels of aluminum foil related contaminants in the patients is bound to be procedure and tissue dependent.
The timely and quantitative analysis of serum or plasma aluminum and heavy metal levels in the recipients of grafts that were in contact with aluminum foil could once and for all resolve this issue. Aluminum serum/plasma levels are indicative for recent high aluminum exposure or uptake by a person or an animal (Kausz et al. 1999; Ghori and Yaqub 1999; Klein et al. 1993; Tietz 1926).
The aluminum and heavy metal levels in the skin cryo preservation solution, however, are very low (below the detection limit or trace element quantities), even after an unusually long contact time (10 years), and therefore suggest that the contaminant levels in the recipient patient are probably negligible.
In the past, sterilized food-grade aluminum foil was often used as a primary wound dressing. Aluminum foil therapy was introduced by Steinhardt in 1924 and since then it was mostly used in burns but also in ulcers. The advantages of aluminum foil dressings, which were historically described are: readily available (Johns 1949; Hambury 1957), easy to sterilize (Johns 1949; Hambury 1957), non-toxic (Johns 1949; Hambury 1957), absence of sensitivity reactions (Hambury 1957), non-expensive (Johns 1949; Hambury 1957), easy to apply (Johns 1949), prevents crust formation (McAvoy et al. 1979), bacteriostatic (Haeger 1963), non-adherent to sutures (Southwood 1951; McAvoy et al. 1979) and comfortable for the patients (Johns 1949; Southwood 1951; McAvoy et al. 1979). In 2005, Muneuchi et al. successfully treated gangrene as a result of malignant rheumatoid arthritis with aluminum foil combined with bFGF (Muneuchi et al. 2005). In the seventies, Poole and colleagues measured no significant upsurge in serum or plasma aluminum levels in patients in whom sterilized food-grade aluminum foil was used as a temporary wound dressing (Poole et al. 1979).
In addition we would like to stress that aluminum is the most abundant metallic element on Earth and this since the origin of life. No aluminum-specific biological function has been reported, neither were significant intoxications, with the exception of some Chronic Renal Failure situations (D’Haese et al. 1999). A recent study showed that there is no association between the aluminum content of bone and mortality risk (Hellstrom et al. 2008).
While aluminum has been described as a potential trigger of apoptosis (Ganrot 1986; Franchini et al. 2009), an histological evaluation did not reveal any sign of this process in our cryo preserved skin tissue.
Conclusion
The small amounts of aluminum and heavy metals that leached into the cryo preservation medium had no effect on the quality of the cryo preserved donor skin allograft. A retrospective analysis revealed no relevant adverse effects in the recipient patients. A thorough rinsing of cryo preserved donor skin allograft before clinical use remains a mandatory procedural step, even if only to remove the often toxic cryo protectant. Further studies could focus on the determination of aluminum and heavy metal concentrations in human tissue grafts that came into contact with aluminium foil and/or the subsequent plasma/serum levels in the recipient patients.
Open Access
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