Abstract
Colorimetric sensor arrays incorporating red, green, and blue (RGB) image analysis use value changes from multiple sensors for the identification and quantification of various analytes. RGB data can be easily obtained using image analysis software such as ImageJ. Subsequent chemometric analysis is becoming a key component of colorimetric array RGB data analysis, though literature contains mainly principal component analysis (PCA) and hierarchical cluster analysis (HCA). Seeking to expand the chemometric methods toolkit for array analysis, we explored the performance of nine chemometric methods were compared for the task of classifying 631 solutions (0.1 to 3 M) of acetic acid, malonic acid, lysine, and ammonia using an eight sensor colorimetric array. PCA and LDA (linear discriminant analysis) were effective for visualizing the dataset. For classification, linear discriminant analysis (LDA), (k nearest neighbors) KNN, (soft independent modelling by class analogy) SIMCA, recursive partitioning and regression trees (RPART), and hit quality index (HQI) were very effective with each method classifying compounds with over 90% correct assignments. Support vector machines (SVM) and partial least squares - discriminant analysis (PLS-DA) struggled with ~85 and 39% correct assignments, respectively. Additional mathematical treatments of the data set, such as incrementally increasing the exponents, did not improve the performance of LDA and KNN. The literature precedence indicates that the most common methods for analyzing colorimetric arrays are PCA, LDA, HCA, and KNN. To our knowledge, this is the first report of comparing and contrasting several more diverse chemometric methods to analyze the same colorimetric array data.
Highlights
The examination of digital images in analytical chemistry has increased by more than 87% from 2005 to 2015, tracking with the increased availability of imaging devices (Capitán-Vallvey, López-Ruiz, Martínez-Olmos, Erena, & Palma, 2015)
We investigated the performance of hierarchical cluster analysis (HCA), linear discriminant analysis (LDA), k-nearest neighbors (KNN), and hit quality index (HQI) in classifying samples of water, HCl (0.5 - 10 M), and NaOH (0.5 - 10 M) using an eight sensor colorimetric sensor array (Kangas, 2018)
While HCA and principal component analysis (PCA) are popular chemometric methods, we sought to explore the use of other algorithms to compare and contrast their usefulness in qualitative and quantitative analysis
Summary
The examination of digital images in analytical chemistry has increased by more than 87% from 2005 to 2015, tracking with the increased availability of imaging devices (Capitán-Vallvey, López-Ruiz, Martínez-Olmos, Erena, & Palma, 2015). Colorimetric arrays are typically composed of 3-40 sensors that can interact with analytes and change color upon molecular interactions (Burks et al, 2010; Li, Jang, Askim, & Suslick, 2015; Salles, Meloni, de Aaujo, & Paixão, 2014). Various types of color changing sensors have been utilized in sensor arrays including pH indicators, metalloporphyrins, solvatochromic dyes, redox indicators, metal salts, ionic liquids, and nanoparticles (Askim et al, 2013; Galpothdeniya et al, 2015). The previously mentioned analyte – sensor interactions allow for a dynamic versatility and high applicability of colorimetric sensor arrays (Suslick, 2004). Effective arrays typically have the following criteria: high selectivity, high sensitivity, the ability to detect many analytes with the fewest numbers of sensors, and yield RGB data that can be analyzed via statistical analysis methods http://ijc.ccsene t.org
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