[BioC] Agilent Arrays
Michael Kirk
michael_kirk at wmi.usyd.edu.au
Mon Jun 27 06:37:20 CEST 2005
Quoting Naomi Altman <naomi at stat.psu.edu>:
> Kirk,
> You have missed my point about the 50 control spots. These are all the
> SAME oligo.
> The correlation here is induced by the array, not by the RNA concentration,
> hybridization efficiency, etc.
OK, if it's the same oligo then that does indicate a spot, or hybridization
effect. Not suprising I guess. Out of curiosity - did you quantify the size
of the effect? I.e. was the inter replicate within slide variation of significant
size relative to whatever variation may be expected between treatments?
Michael
>
> The reason that the two color analysis is supposed to be more efficient
> than 1 channel is the positive correlation between the
> errors for the 2 channels on the same spot. If the channels are
> uncorrelated, then there is no spot effect and using the differences is no
> better than using the 2 channels.
>
> The single channel analysis can be used, providing that you use a linear
> mixed model that includes a random effect for array (and, in the case of
> multiple spots per gene) for
> spot(array).
>
> --Naomi
>
>
> At 09:20 PM 6/26/2005, Michael Kirk wrote:
> >While I agree that it is probably a bad idea to use single channel
> >analysis on two colour arrays, some of the arguments presented here
> >are a little troubling.
> >
> >The observation that the intra slide correlation is 0.8 doesn't, to my
> >mind, show anything unless it is high relative to inter slide
> >correlation. Regardless of what treatments are applied to the samples,
> >all mouse (say) samples would be expected to have roughly similar
> >(array wise) expression profiles. This is partly a reflection of the
> >fact that many genes may not vary between treatments and different
> >probes will have different hybridization efficiencies (i.e. some spots
> >will always have low intensities and some high).
> >
> >Secondly, IF the single channel intensities were in fact highly
> >accurate, then it is the two colour analysis that would be inefficient
> >(in terms of number of arrays required). The two colour idea is
> >essentially to overcome noise, particularly noise due to variation in
> >the printed spots between slides (i.e. the chemical/physical
> >properties of a spot for a given gene may vary between slides). In
> >this case the variation is assumed to affect each hybridized sample
> >similarly (multiplicatively) and by taking the ratio this variation is
> >removed. A fine idea, but it does leave us with less information than
> >if the slide quality was sufficient for this to to be unnecessary.
> > >From the two colour analysis of a single slide we have a set of
> >ratios, which may then be compared between slides. From the single
> >channel analysis of a two colour hybridization we have two sets of
> >measurements, which also may be compared between slides.
> >
> >With two colour analysis, only three samples can be compared using two
> >slides, whereas if the single channel analysis was justified (and note
> >I am not say it is, only discussing the arguments given against it),
> >then four samples can be compared.
> >
> >Michael
> >
> > > Wolfgang,
> > >
> > > Naomi is refering to what I call the "intraspot" correlation, see for
> > > example the intraspotCorrelation() function in the limma package, and
> > it is
> > > critically important. The correlation isn't a bad thing, nor is it
> > > restricted to poor quality arrays. Rather it means that contrasts
> > estimated
> > > within a spot are highly accurate. It is what makes the two-colour
> > > technology intrinsically more accurate than one channel technology, other
> > > things being equal. See http://www.statsci.org/smyth/pubs/ISI2005-116.pdf
> > > for some discussion.
> > >
> > > Basically, you're saying that if the arrays are very high quality, you can
> > > get away with an inefficient analysis. Why not do it properly and get the
> > > full benefit of the high quality arrays? My experience is that high
> > quality
> > > Agilent arrays can beat affy for accuracy if treated properly.
> > >
> > > Gordon
> > >
> > > >Date: Thu, 23 Jun 2005 15:29:38 +0100 (BST)
> > > >From: "Wolfgang Huber" <huber at ebi.ac.uk>
> > > >Subject: Re: [BioC] Agilent Arrays
> > > >To: "Naomi Altman" <naomi at stat.psu.edu>
> > > >Cc: bioconductor at stat.math.ethz.ch
> > > >
> > > >Hi Naomi,
> > > >
> > > >and why is that important? Also, what is the within gene correlation
> > > >between green foreground of array 1 and green foreground of array 2?
> > > >
> > > >Bw
> > > > Wolfgang
> > > >
> > > ><quote who="Naomi Altman">
> > > > > I am working with Agilent arrays on which we have spotted many
> > replicates
> > > > > of the control spots.
> > > > > The within gene correlation between red and green forground is
> > about 0.8
> > > > > for the unnormalized data - i.e. pretty high!
> > > > >
> > > > > --Naomi
> >
> >[snip]
> >
> >_______________________________________________
> >Bioconductor mailing list
> >Bioconductor at stat.math.ethz.ch
> >https://stat.ethz.ch/mailman/listinfo/bioconductor
>
> Naomi S. Altman 814-865-3791 (voice)
> Associate Professor
> Bioinformatics Consulting Center
> Dept. of Statistics 814-863-7114 (fax)
> Penn State University 814-865-1348 (Statistics)
> University Park, PA 16802-2111
>
>
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