Cationic silicone based paper impregnation agent for the protection of historical paper against fungal growth. Detection and quantification of fungi using micro-invasive fluorescence microscopy and non-invasive FTIR spectroscopy

IF 3.5 2区 综合性期刊 0 ARCHAEOLOGY
Janez Kosel , Lea Legan , Matej Bračič , Polonca Ropret
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引用次数: 0

Abstract

Even though contamination of historical paper by moulds causes aesthetic, physical, and biochemical biodeterioration, dissolving cellulose fibers and inks, the currently applied physical and chemical disinfection methods are either extremely dangerous to human health (ethylene oxide), may harm the underlying support material, or their efficiency is dependent on fungal species, many of which may resist. Therefore, our aim was to test a new paper impregnation agent, aminopropyl-terminated polydimethylsiloxane (ATP), in regards to its biological potency, ease of handling and support material safety. According to the Gelest Inc. (Morrisville, PA 19067) safety data sheet DMS-A31, ATP in solution causes eye irritation, but in dry from is relatively safe. Our biofouling experiments with four cellulase-active fungal strains, originally isolated from historical books, were conducted directly on impregnated and aged paper at verifying concentrations of ATP and at a relative humidity of 95 %. Fungal biofilm development was quantified using micro-invasive fluorescence microscopy and after incubation non-invasive FTIR spectroscopy was also employed. 3D surface topography scan results showed that ATP impregnation at a concentration of 30 % does not harm the visible structural characteristics of the tested paper and no alterations in surface roughness parameters were observed and is therefore safe for the supporting material. At least a 10 % paper impregnation was needed for an effective suppression of fungal biofilm development and tolerance to lower concentrations was species dependent, with Penicillium canescens ZIM-9717 tolerating 1 % of ATP and Aspergillus niger ZIM-9721 tolerating 1 % and 5 % of ATP. Lastly, we have shown that portable “on the spot” non-invasive FTIR spectroscopy in reflection mode can be effectively used for a rapid but highly sensitive detection and monitoring of mould biofilms on paper support materials. This is important, because sampling and fluorescence dye staining in fluorescence microscopy, will harm the integrity of cultural heritage books and documents. Therefore, non-invasive FTIR spectroscopy can provide for an initial overview or insight into the microbiological condition of library and paper materials.

阳离子硅基纸张浸渍剂,用于保护历史纸张,防止真菌生长。利用微侵袭荧光显微镜和非侵袭傅立叶变换红外光谱检测和量化真菌
尽管霉菌污染历史纸张会造成美学、物理和生物化学方面的生物劣化,溶解纤维素纤维和油墨,但目前使用的物理和化学消毒方法要么对人体健康危害极大(环氧乙烷),要么可能会伤害底层支撑材料,要么其效率取决于真菌种类,其中许多真菌可能会产生抗药性。因此,我们的目的是测试一种新的纸张浸渍剂--氨基丙基端聚二甲基硅氧烷(ATP)--的生物效力、易处理性和支持材料安全性。根据 Gelest 公司(Morrisville, PA 19067)的安全数据表 DMS-A31,ATP 在溶液中会刺激眼睛,但在干燥状态下相对安全。我们用最初从古籍中分离出来的四种纤维素酶活性真菌菌株进行了生物污损实验,实验直接在浸渍过的陈旧纸张上进行,ATP 的浓度经过验证,相对湿度为 95%。使用微创荧光显微镜对真菌生物膜的发展进行量化,并在培养后使用非侵入式傅立叶变换红外光谱。三维表面形貌扫描结果表明,浓度为 30% 的 ATP 浸渍不会损害测试纸张的可见结构特征,也不会改变表面粗糙度参数,因此对支撑材料是安全的。要有效抑制真菌生物膜的形成,至少需要 10% 的纸张浸渍,而且对较低浓度的耐受性取决于物种,卡氏青霉 ZIM-9717 可耐受 1% 的 ATP,黑曲霉 ZIM-9721 可耐受 1% 和 5% 的 ATP。最后,我们已经证明,采用反射模式的便携式 "现场 "无创傅立叶变换红外光谱仪可有效用于快速、高灵敏度地检测和监测纸张支撑材料上的霉菌生物膜。这一点非常重要,因为荧光显微镜中的取样和荧光染料染色会损害文化遗产书籍和文件的完整性。因此,非侵入式傅立叶变换红外光谱仪可以对图书馆和纸质材料的微生物状况进行初步概述或深入了解。
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来源期刊
Journal of Cultural Heritage
Journal of Cultural Heritage 综合性期刊-材料科学:综合
CiteScore
6.80
自引率
9.70%
发文量
166
审稿时长
52 days
期刊介绍: The Journal of Cultural Heritage publishes original papers which comprise previously unpublished data and present innovative methods concerning all aspects of science and technology of cultural heritage as well as interpretation and theoretical issues related to preservation.
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