Julie Wertz scite author profile

Historical and archaeological textiles are among the most crucial and vulnerable records of our social and cultural history. Analysis of organic colorants found in these materials is unquestionably one of the most powerful tools to understand historical developments, cultural exchanges, and progress in science and technology. Natural anthraquinones represent the most commonly used natural colorants for textile dyeing until the late 19 th century. The identification of anthraquinones in cultural heritage objects is a challenging task due to the small size of historical samples, diversity of potential dye sources, variable extraction procedures and dyeing methods, complex chemical constitution, structurally analogous chromophores, and possible presence of degradation products and contaminants. Developments in dye analysis of historical interest have originated and expanded along with the general advances in analytical science. In the last few decades, a close cooperation between science and cultural heritage disciplines contributed enormously to this field. The topic of historical dyes and their analysis in textiles, artworks, archaeological objects and cultural heritage materials has been reviewed several times in the last fifteen years. However, no review has been published to-date exclusively on the analysis of anthraquinone colorants in historical and archaeological textiles. Overall, liquid chromatography (LC)-based techniques have been the most widely used method for anthraquinone dye analysis. Owing to increasing demand of minimally invasive/non-invasive techniques, recent developments of novel techniques have resulted in the availability of many alternative/complementary methods to LC-based analysis. This review begins with a short overview of sources, chemistry and importance of natural anthraquinone dyes found in historical textiles before turning to a detailed discussion on developments involving established and emerging analytical techniques of anthraquinone dye analysis for textile cultural heritage materials. To illustrate the state-of-the-art, representative examples of analytical techniques highlighting their advantages, limitations and applicability are also presented.

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A bimodular oxidoreductase mediates the specific reduction of phylloquinone (vitamin K1) in chloroplasts

Furt¹,

Oostende²,

Widhalm

et al. 2010

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SUMMARYPlants and certain species of cyanobacteria are the only organisms capable of synthesizing phylloquinone (vitamin K 1 for vertebrates), which they use as an electron carrier during photosynthesis. Recent studies, however, have identified a plastidial pool of non-photoactive phylloquinone that could be involved in additional cellular functions. Here, we characterized an Arabidopsis bimodular enzyme -the At4g35760 gene product -comprising an integral domain homologous to the catalytic subunit of mammalian vitamin K epoxide reductase (VKORC1, EC 1.1.4.1) that is fused to a soluble thioredoxin-like moiety. GFP-fusion experiments in tobacco mesophyll cells established that the plant protein is targeted to plastids, and analyses of transcript and protein levels showed that expression is maximal in leaf tissues. The fused and individual VKORC1 domains were separately expressed in yeast, removing their chloroplast targeting pre-sequence and adding a C-terminal consensus signal for retention in the endoplasmic reticulum. The corresponding microsomal preparations were equally effective at mediating the dithiotreitol-dependent reduction of phylloquinone and menaquinone into their respective quinol forms. Strikingly, unlike mammalian VKORC1, the Arabidopsis enzyme did not reduce phylloquinone epoxide, and was resistant to inhibition by warfarin. The isoprenoid benzoquinone conjugates plastoquinone and ubiquinone were not substrates, establishing that the plant enzyme evolved strict specificity for the quinone form of naphthalenoid conjugates. In vitro reconstitution experiments established that the soluble thioredoxin-like domain can function as an electron donor for its integral VKORC1 partner.

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Effect of carbon paper substrate of the gas diffusion layer on the performance of proton exchange membrane fuel cell

Lin

Wertz²,

Ahmad³

et al. 2010

Electrochimica Acta

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Wire rod coating process of gas diffusion layers fabrication for proton exchange membrane fuel cells

Kannan¹,

Sadananda²,

Parker³

et al. 2008

Journal of Power Sources

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Julie Wertz

Gas diffusion layer for proton exchange membrane fuel cells—A review

Analytical methods for determination of anthraquinone dyes in historical textiles: A review

A bimodular oxidoreductase mediates the specific reduction of phylloquinone (vitamin K1) in chloroplasts

Effect of carbon paper substrate of the gas diffusion layer on the performance of proton exchange membrane fuel cell

Wire rod coating process of gas diffusion layers fabrication for proton exchange membrane fuel cells

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