Partek Flow Documentation

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The format of the output is the same as the input data format, the node is called Normalized counts. This data node can be selected and normalized further using the same task.

Selecting Methods

Select whether you want your data normalized on a per sample or per feature basis (Figure 2). Some transformations are performed on each value independently of others e.g. log transformation, and you will get an identical result regardless of your choice.

 


Numbered figure captions
SubtitleTextTransformation can be done on samples or on features
AnchorNametransform-on

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Note that each task can only perform normalization on samples or features. If you wish to perform both transformations, run two normalization tasks successively. To normalize the data, click on a method from the left panel, then drag and drop the method to the right panel. Add all normalization methods you wish to perform. Alternatively, you can click on the green plus button () on each method to add it. Multiple methods can be added to the right panel and they will be processed in the order they are listed. You can change the order of methods by dragging each method up or down. To remove a method from the Normalization order panel, click the minus button () to the right of the method. Click Finish, when you are done choosing the normalization methods you have chosen.

Recommended Methods

For some data nodes, recommended methods are available:

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SubtitleTextNormalization using Partek’s recommended method
AnchorNamerecommended-methods-button

Normalization Methods

Below is the notation that will be used to explain each method:

SymbolMeaning
SSample (or cell for single cell data node)
FFeature
Xsf

Value of sample S from feature F (if normalization is performed on a quantification data node, this would be the raw read counts)

TXsf

transformed value of Xsf

CConstant value
bBase of log

 


  • Absolute value
    TXsf = | Xsf |
  • Add
    TXsf = Xsf + C  
    a constant value C needs to be specified
  • Antilog
    TXsf = bxsf
    A log base value b needs to be specified from the drop-down list; any positive number can be specified when Custom value is chosen
  • CLR (centered log ratio)
    TXsf =ln((Xsf +1)/geom (Xsf +1) +1)
    geom is geometric mean of either observation or feature. We recommend to perform this normalization on observation for CITE seq data.

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    1. Remove all the features that have 0 reads in all samples.
    2. Calculate the effective library size per sample: effective library size =  (raw library size (in millions))*((upper quartile for a particular sample)/ (geometric mean of upper quartiles in all the samples))
    3. Get the normalized counts by dividing the raw counts per feature by the effective library size (for the respective sample)

Normalization Report

The Normalization report includes the Normalization methods used, a Feature distribution table, Box-whisker plots of the Expression signal before and after normalization, and Sample histogram charts before and after normalization. Note that all visualizations are disabled for results with more than 30 samples.

Normalization methods

A summary of the normalization methods performed. They are listed by the order they were performed.

Feature distribution table  

A table that presents descriptive statistics on each sample, the last row is the grand statistics across all samples (Figure 4).

 


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SubtitleTextFeature distribution statistic information on each sample and across all the samples
AnchorNamefeature-distribution-statistic

Expression signal

These box-whisker plots show the expression signal distribution for each sample before and after normalization. When you mouse over on each bar in the plot, a balloon would show detailed percentile information (Figure 5).

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SubtitleTextBox-whisker plot displays expression signal distribution for each sample
AnchorNamebox-whisker-plot

Sample histogram

A histogram is displayed for data before and after it is normalized. Each line is a sample, where the X axis is the range of the data in the node and the Y-axis is the frequency of the value within the range. When you mouse over a circle which represent a center of an interval, detailed information will appear in a balloon  (Figure 6).  It includes:

  • The sample name.
  • The range of the interval, “[ “represent inclusive, “)” represent exclusive.
  • The frequency value within the interval

 


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SubtitleTextSample histogram. Mousing over shows detailed information about the interval. This includes sample name, range and frequency of the selected sample.
AnchorNamesample-histogram

References

 


  1. Bolstad BM, Irizarry RA, Astrand M, Speed, TP. A Comparison of Normalization Methods for High Density Oligonucleotide Array Data Based on Bias and Variance. Bioinformatics. 2003; 19(2): 185-193.
  2. Mortazavi A, Williams BA, McCue K, Schaeffer L, Wold B. Mapping and quantifying mammalian transcriptomes by RNA-Seq. Nat Methods. 2008; 5(7): 621–628.
  3. Bullard JH, Purdom E, Hansen KD, Dudoit S. Evaluation of statistical methods for normalization and differential expression in mRNA-Seq experiments. BMC Bioinformatics. 2010; 11: 94.
  4. Robinson MD, Oshlack A. A scaling normalization method for differential expression analysis of RNA-seq data. Genome Biol. 2010; 11: R25.
  5. Dillies MA, Rau A, Aubert J et al. A comprehensive evaluation of normalization methods for Illumina high-throughput RNA sequencing data analysis. Brief Bioinform. 2013; 14(6): 671-83.
  6. Wagner GP, Kin K, Lynch VJ. Measurement of mRNA abundance using RNA-seq data. Theory Biosci. 2012; 131(4): 281-5.
  7. Ritchie ME, Phipson B, Wu D et al. Limma powers differential expression analyses for RNA-sequencing and microarray studies. Nucleic Acids Res. 2015; 43(15):e97.

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