Improved peak detection and quantification of mass spectrometry data acquired from surface-enhanced laser desorption and ionization by denoising spectra with the undecimated discrete wavelet transform

Coombes, Kevin R.; Tsavachidis, Spiridon; Morris, Jeffrey S.; Baggerly, Keith A.; Hung, Mien‐Chie; Kuerer, Henry Mark

doi:10.1002/pmic.200401261

Cited by 282 publications

(299 citation statements)

References 24 publications

(18 reference statements)

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“…After applying the algorithm to the bovine cytochrome C and COFRADIC data sets, we could conclude that the removal of the normal error term ε in (1) by undecimated continuous wavelet transform [11] has only a minor effect on the intensity of the peptide peaks. The baseline correction is fast and yields results comparable to, e.g., LOWESS.…”

Section: Discussionmentioning

confidence: 98%

“…Nevertheless, during the low-level processing (light gray labels in Fig. 1), the additive noise is removed from the mass spectrum by using the undecimated discrete wavelet transform proposed by Baggerly et al [11] The baseline is removed to improve the reproducibility. To decrease the complexity of a mass spectrum, the data are reduced without loss of relevant information, i.e., the information about the isotopic distribution is retained.…”

Section: Load New Fractionmentioning

confidence: 99%

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A strategy for the prior processing of high‐resolution mass spectral data obtained from high‐dimensional combined fractional diagonal chromatography

Valkenborg

Thomas²,

Krols³

et al. 2008

J. Mass Spectrom.

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Combined fractional diagonal chromatography (COFRADIC) is a novel suite of gel-free technologies for the identification of biomarkers in complex peptide mixtures. For this purpose, reversed-phase high performance liquid chromatography (HPLC) technology and, in this case, matrix assisted laser desorption /ionization-time of flight (MALDI-TOF) mass spectrometers are extensively used. The particular characteristic of COFRADIC mass spectrometry data is the high number of chromatographic fractions, over which a peptide can be scattered. This can obstruct the quantification of the peptide abundance in the biological sample, which is required for statistical analysis. On the other hand, because of the superior peptide sorting properties of the methodology, the mass spectra become less crowded. Consequently, each peptide appears in a mass spectrum as a series of peaks with peak heights proportional to the probability of occurrence of the isotopic variants of the peptide. In this manuscript, we propose an analysis strategy concerned with the preprocessing of COFRADIC mass spectra prior to a downstream statistical analysis. The preprocessing algorithm produces for each mass spectrum a peptide list by exploiting the characteristic features that should be associated with peaks corresponding to an isotopically resolved cluster of peptide peaks. This reduction step is necessary to facilitate the clustering used in a next step to assemble the validated monoisotopic peptide peaks found over several fractions into a single peptide abundance. To assess the performance of the algorithm, two technical experiments were conducted. The proposed strategy is memory and computationally efficient.

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Section: Discussionmentioning

confidence: 98%

Section: Load New Fractionmentioning

confidence: 99%

A strategy for the prior processing of high‐resolution mass spectral data obtained from high‐dimensional combined fractional diagonal chromatography

Valkenborg

Thomas²,

Krols³

et al. 2008

J. Mass Spectrom.

View full text Add to dashboard Cite

show abstract

“…Wavelet denoising strategies were also used (Ceballos et al 2008) on pattern recognition in CE. Similar wavelet based denoising strategies to those cited above have also been applied to liquid chromatography data (Barclay and Bonner 1997;Shao et al 2004), Raman spectroscopy (Hu et al 2007), mass spectrometry data (Barclay and Bonner 1997;Coombes et al 2005), as well as numerous other areas of research (Jagtiani et al 2008;Komsta 2009). The DWT is sufficient in many scenarios when removing high and low frequency noise from signals.…”

Section: Wavelet Transformation For Noise Removalmentioning

confidence: 99%

Signal Processing Methods for Capillary Electrophoresis

Stewart¹,

Gideoni²,

Zhu³

2011

Systems and Computational Biology - Bioinformatics and Computational Modeling

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“…In the extracted calcium signals, noisy signals will most likely be induced by the bias of segmentation, displacement correction, and intensity normalization. To suppress these noisy signals, the undecimated discrete wavelet transform (UDWT) (Coombes et al 2005) is employed. Figure 6 provides an example of extracted calcium signals.…”

Section: Calcium Signal Analysismentioning

confidence: 99%

Workflow and Methods of High-Content Time-Lapse Analysis for Quantifying Intracellular Calcium Signals

Zhou

Zhu

et al. 2008

Neuroinform

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Calcium ions (Ca 2+ ) play a fundamental role in a variety of physiological functions in many cell types by acting as a secondary messenger. Variation of intracellular Ca 2+ concentration ([Ca 2+ ] i ) is often observed when the cell is stimulated. However, it is a challenging task to automatically quantify intracellular [Ca 2+ ] i in a population of cells. In this study, we present a workflow including specific algorithms for the automated intracellular calcium signal analysis using high-content, time-lapse cellular images. The experimental validations indicate the effectiveness of the proposed workflow and algorithms. We applied the workflow to analyze the intracellular calcium signals induced by different concentrations of H 2 O 2 in the cell lines transfected by presenilin-1 (PS-1) that is known to be closely related to the familial Alzheimer's disease (FAD). The analysis results

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Improved peak detection and quantification of mass spectrometry data acquired from surface-enhanced laser desorption and ionization by denoising spectra with the undecimated discrete wavelet transform

Cited by 282 publications

References 24 publications

A strategy for the prior processing of high‐resolution mass spectral data obtained from high‐dimensional combined fractional diagonal chromatography

A strategy for the prior processing of high‐resolution mass spectral data obtained from high‐dimensional combined fractional diagonal chromatography

Signal Processing Methods for Capillary Electrophoresis

Workflow and Methods of High-Content Time-Lapse Analysis for Quantifying Intracellular Calcium Signals

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