ToF-SIMS data analysis for complex plant tissue samples using multivariate analysis and G-SIMS

Recently, controlled production of plants to enhance specific ingredients, such as sinigrin in Wasabi effective for antibacterial and anticancer, in the plants has become more important in order to use the ingredients efficiently. It is, however, difficult to develop a plant production method for co...

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Veröffentlicht in:	Surface and interface analysis 2014-11, Vol.46 (S1), p.131-135
Hauptverfasser:	Aoyagi, Satoka, Kodani, Noriko, Yano, Akira, Asao, Toshiki, Iwai, Hideo, Kudo, Masahiro
Format:	Artikel
Sprache:	eng
Schlagworte:	Antiinfectives and antibacterials Data processing G-SIMS Ingredients Insulation Interface analysis Multivariate analysis multivariate curve resolution plant tissue Production methods sinigrin Spectra ToF-SIMS
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container_title	Surface and interface analysis
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creator	Aoyagi, Satoka Kodani, Noriko Yano, Akira Asao, Toshiki Iwai, Hideo Kudo, Masahiro
description	Recently, controlled production of plants to enhance specific ingredients, such as sinigrin in Wasabi effective for antibacterial and anticancer, in the plants has become more important in order to use the ingredients efficiently. It is, however, difficult to develop a plant production method for controlling the sinigrin amount, because the sinigrin production mechanism is not clear. Therefore, it is crucial to evaluate distribution and metabolic pathways of sinigrin and related molecules in the wasabi tissue. Because time‐of‐flight (ToF)‐SIMS provides molecular distributions of insulation samples including plant tissues on a submicron scale, it is useful for such a purpose. On the other hand, interpretation of intricate ToF‐SIMS spectra of complex samples is often difficult. Recently, multivariate analysis techniques, such as principal component analysis and multivariate curve resolution, successfully applied into a variety of scientific fields have been also introduced into ToF‐SIMS data. Moreover, gentle secondary ion mass spectrometry (G‐SIMS), developed for analyzing static‐SIMS spectra in terms of the degree of fragmentation, has recently been applied to various samples. In this study, sections of Wasabi petioles were evaluated with ToF‐SIMS and the data analysis techniques to clarify the distribution of sinigrin molecule in the wasabi tissue. A combination of multivariate analysis and G‐SIMS worked effectively to interpret the complex ToF‐SIMS data of the plant tissue. As a result, the detailed distribution of sinigrin in the plant tissue was indicated by ToF‐SIMS and the data analysis techniques. Copyright © 2014 John Wiley & Sons, Ltd.
doi_str_mv	10.1002/sia.5588
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In this study, sections of Wasabi petioles were evaluated with ToF‐SIMS and the data analysis techniques to clarify the distribution of sinigrin molecule in the wasabi tissue. A combination of multivariate analysis and G‐SIMS worked effectively to interpret the complex ToF‐SIMS data of the plant tissue. As a result, the detailed distribution of sinigrin in the plant tissue was indicated by ToF‐SIMS and the data analysis techniques. 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Interface Anal</addtitle><description>Recently, controlled production of plants to enhance specific ingredients, such as sinigrin in Wasabi effective for antibacterial and anticancer, in the plants has become more important in order to use the ingredients efficiently. It is, however, difficult to develop a plant production method for controlling the sinigrin amount, because the sinigrin production mechanism is not clear. Therefore, it is crucial to evaluate distribution and metabolic pathways of sinigrin and related molecules in the wasabi tissue. Because time‐of‐flight (ToF)‐SIMS provides molecular distributions of insulation samples including plant tissues on a submicron scale, it is useful for such a purpose. On the other hand, interpretation of intricate ToF‐SIMS spectra of complex samples is often difficult. Recently, multivariate analysis techniques, such as principal component analysis and multivariate curve resolution, successfully applied into a variety of scientific fields have been also introduced into ToF‐SIMS data. Moreover, gentle secondary ion mass spectrometry (G‐SIMS), developed for analyzing static‐SIMS spectra in terms of the degree of fragmentation, has recently been applied to various samples. In this study, sections of Wasabi petioles were evaluated with ToF‐SIMS and the data analysis techniques to clarify the distribution of sinigrin molecule in the wasabi tissue. A combination of multivariate analysis and G‐SIMS worked effectively to interpret the complex ToF‐SIMS data of the plant tissue. As a result, the detailed distribution of sinigrin in the plant tissue was indicated by ToF‐SIMS and the data analysis techniques. 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On the other hand, interpretation of intricate ToF‐SIMS spectra of complex samples is often difficult. Recently, multivariate analysis techniques, such as principal component analysis and multivariate curve resolution, successfully applied into a variety of scientific fields have been also introduced into ToF‐SIMS data. Moreover, gentle secondary ion mass spectrometry (G‐SIMS), developed for analyzing static‐SIMS spectra in terms of the degree of fragmentation, has recently been applied to various samples. In this study, sections of Wasabi petioles were evaluated with ToF‐SIMS and the data analysis techniques to clarify the distribution of sinigrin molecule in the wasabi tissue. A combination of multivariate analysis and G‐SIMS worked effectively to interpret the complex ToF‐SIMS data of the plant tissue. As a result, the detailed distribution of sinigrin in the plant tissue was indicated by ToF‐SIMS and the data analysis techniques. 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subjects	Antiinfectives and antibacterials Data processing G-SIMS Ingredients Insulation Interface analysis Multivariate analysis multivariate curve resolution plant tissue Production methods sinigrin Spectra ToF-SIMS
title	ToF-SIMS data analysis for complex plant tissue samples using multivariate analysis and G-SIMS
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