nec: NormExp Background Correction and Normalization Using Control Probes

Description

Perform normexp background correction using negative control probes and quantile normalization using negative and positive control probes. Particularly useful for Illumina BeadChips.

Usage

nec(x, status=NULL, negctrl="negative", regular="regular", offset=16,
    robust=FALSE, detection.p="Detection")
neqc(x, status=NULL, negctrl="negative", regular="regular", offset=16,
    robust=FALSE, detection.p="Detection", ...)

Arguments

object of class EListRaw or matrix containing raw intensities for regular and control probes from a series of microarrays.

status

character vector giving probe types. Defaults to x$genes$Status if x is an EListRaw object.

negctrl

character string identifier for negative control probes.

regular

character string identifier for regular probes, i.e., all probes other than control probes.

offset

numeric value added to the intensities after background correction.

robust

logical. Should robust estimators be used for the background mean and standard deviation?

detection.p

dection p-values. Only used when no negative control probes can be found in the data. Can be a numeric matrix or a character string giving the name of the component of x$other containing the matrix.

...

any other arguments are passed to normalizeBetweenArrays.

Value

nec produces a EListRaw-class or matrix object of the same dimensions as x containing background-corrected intensities, on the raw scale. neqc produces a EList-class or matrix object containing normalized log2 intensities, with rows corresponding to control probes removed.

Details

neqc performs background correction followed by quantile normalization, using negative control probes for background correction and both negative and positive controls for normalization (Shi et al, 2010). nec is similar but performs background correction only. When control data are available, these function call normexp.fit.control to estimate the parameters required by normal+exponential(normexp) convolution model with the help of negative control probes, followed by normexp.signal to perform the background correction. If x contains background intensities x$Eb, then these are first subtracted from the foreground intensities, prior to normexp background correction. After background correction, an offset is added to the data.

When expression values for negative controls are not available, the detection.p argument is used instead, In that case, these functions call normexp.fit.detection.p, which infers the negative control probe intensities from the detection p-values associated with the regular probes. The function outputs a message if this is done. For more detailed descriptions of the arguments x, status, negctrl, regular and detection.p, please refer to functions normexp.fit.control, normexp.fit.detection.p and read.ilmn. Both nec and neqc perform the above steps. neqc continues on to quantile normalize the background-corrected intensities, including control probes. After normalization, the intensities are log2 transformed and the control probes are removed.

References

Shi W, Oshlack A and Smyth GK (2010). Optimizing the noise versus bias trade-off for Illumina Whole Genome Expression BeadChips. Nucleic Acids Research 38, e204. http://nar.oxfordjournals.org/content/38/22/e204

Examples

Run this code

# neqc normalization for data which include control probes
x <- read.ilmn(files="sample probe profile.txt", ctrlfiles="control probe profile.txt")
y <- neqc(x)
fit <- lmFit(y,design)

# Same thing but in separate steps:
x.b <- nec(x)
y <- normalizeBetweenArrays(x.b,method="quantile")
y <- y[y$genes$Status=="regular",]

# neqc normalization for data which do not include control probes
xr <- read.ilmn(files="sample probe profile.txt")
yr <- neqc(xr)

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