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We developed GCalignR
primarily as an alignment tool for
GC-FID data based on peak retention times, but other types of data that
contain retention time information for peaks (e.g. GC-MS) are supported
as well. GCalignR
implements a fast and objective method to
cluster putatively homologous substances prior to multivariate
statistical analyses. Using sophisticated visualisations, the resulting
alignments can then be fine tuned. The input format of
GCalignR
is a peak list, which is comprised of retention
times and arbitrary variables (e.g. peak height, peak area) that
characterise each peak in a dataset.
The implemented algorithm is purely based on retention time data,
which is why the quality of the alignment is highly dependent on the
quality of the raw data and the parameters used for the initial peak
detection. In other words: The clearer the peaks are which were
extracted from the chromatograms, the better the alignment will be.
GCalignR
has been created for situations where the main
interest of the research is in exploring broader patterns rather then
the specific function of a certain chemical, which is unlikely to be
determined correctly in all cases when just retention times are used.
Also, we recommend to double-check the resulting alignment with
mass-spectrometry data, where available. Furthermore, replicates that
were analysed using both GC-MS and GC-FID with identical gas
chromatography settings can be aligned together and may be used to
identify peaks and validate alignment results.
This vignette gives an quick introduction into using
GCalignR
, whereas a more detailed description of the
background is found in our manuscript(Ottensmann
et al. 2018) and in the second vignette of the package
“GCalignR: How does the Algorithm work?”.
In the flow diagram below, we visualized the functionality of
GCalignR within a complete workflow of analysing chemical data. After
(1) analysis of the chemical samples with GC-FID, an often proprietary
software is used to extract a list of peaks (retention times, peak area,
also often peak height and other variables). Steps (3)-(7) are the
alignment steps within GCalignR
, detailed below. After
alignment and normalisation, the output can be used as input for
multivariate statistics in other packages such as vegan (8).
The development version can be downloaded from GitHub with the following code:
install.packages("devtools")
devtools::install_github("mottensmann/GCalignR", build_vignettes = TRUE)
The package documentation can be accessed with:
GCalignR
:align_chromatograms
: The entire alignment procedure
is implemented within this function based on three parameter values
described below. Additional parameters allow optional processing
steps.
plot.GCalign
: Diagnostic plots summarise the aligned
dataset.
print.GCalign
: Summarises the alignment process and
lists all arguments to the function call.
gc_heatmap
: Visualises alignment results and enables
to quickly inspect the distribution of substances (i.e aligned peaks)
within the dataset. Furthermore, the deviation from mean retention times
of a given substance can be used to detect potential issues with the
alignment.
check_input
: Checks the format of the input data for
conformity with the requirements and highlights violations.
norm_peaks
: Normalises the abundance measure of
peaks by calculating relative intensities within samples.
as.data.frame.GCalign
: Outputs aligned datasets
within a list of data frames for each variable in the input
data.
We developed an alignment procedure that involves three sequential steps to align and finally match peaks belonging to putatively homologous substances across samples. The first step is to align each sample to a reference sample while maximising overall similarity through linear shifts of retention times. This procedure is often described in the literature as ‘full alignment’. In the second step, individual peaks are sorted into rows based on close similarity of their retention times, a procedure that is often referred to as ‘partial alignment’. Finally, there is still a chance that homologous peaks can be sorted into different, but adjacent, rows in different samples, depending on the variability of their retention times Consequently, a third step merges rows representing putatively homologous substances.
The alignment algorithm implemented in the
align_chromatograms
function contains the following steps:
(Here we refer to a peak list as all extracted peaks from a given sample
chromatogram)
The first step in the alignment procedure consists of an
algorithm that corrects systematic linear shifts between peaks of a
query sample and a fixed reference to account for systematic shifts in
retention times among samples. By default the sample that is most
similar on average to all other samples is automatically selected as
reference. With respect to the user-defined parameter
max_linear_shift
linear shifts shifts are applied to all
retention times of a sample to maximise similarity to the
reference.
The second step in the alignment procedure aligns individual
peaks across samples by comparing the peak retention times of each
sample consecutively with the mean of all previous samples The parameter
max_diff_peak2mean
specifies the allowed deviation between
the retention time of a peak and the mean of previous retention times
within the same row. If the deviation is larger than allowed, matrix
operations are conducted to sort the peaks accordingly.
3.The third step in the alignment procedure accounts for the fact
that a number of homologous peaks will be sorted into multiple rows that
can be subsequently merged The maximum mean difference between two
retention time rows can be specified with the
min_diff_peak2peak
argument.
Delete peaks that occur in just one sample by setting the
delete_single_peak
argument to TRUE
Delete all peaks that occur in negative control samples by
specifying their names as argument to blanks
The statistical analysis of GC-FID or GC-MS data is usually based on
the detection of peaks (i.e. substances) within chromatograms instead of
using the whole profile. Peak can be integrated using proprietary
software or free programs. The peak data derived from a chromatogram
usually contains the retention time of a given peak plus additional
information such as the area under the peak or its height which are used
in the subsequent analysis. GCalignR
uses only the
retention times (and not the mass-spectra, which may not be available,
e.g. when using gas-chromatography coupled to a flame ionization
detector (FID)) to align the peaks across individuals for subsequent
chemometric analysis and pattern detection. The simple assumption is
that peaks with similar retention times represent the same substances.
However, it is recommended to verify this assumption by comparing also
the mass-spectra (if available) of the substances of interest. The input
peak list used in GCalignR
is a plain text file, whereby
all elements should be separated by tabs (with sep = “/t”) or any other
separator, which has to be specified with the sep
argument
(see ?read.table
for a list of separators). The decimal
separator has to be the point.
The first row contains the sample names, whereby every name must be unique. Names should not contain whitespaces and use the underscore as the only special character.
The second row contains the names of the data columns. For
example, if both the retention time of a peak as well as the area under
the peak have been extracted you would write RT area
into
the second line. You can however add more variables such as the peak
height. The variable names should not contain whitespaces and use the
underscore as the only special character.
Starting with the third row, the actual peak data is included,
whereby single samples are concatenated horizontally. Each chromatogram
needs to consist of the same number of columns, whereby at least one
containing retention times is required. In order to use the
functionality of the function norm_peaks
an additional
column containing a concentration measure (e.g. height or area of peaks)
is required. The decimal separator has to be the point (not
comma!).
Naturally, not all chromatograms contain the same number of peaks.
Alternatively to reading a text file, GCalignR
also
accepts lists of data frames. The name of each list element corresponds
to the identity of a sample and the data frame contains the peak data
for this sample (again, the minimum number of columns is one column for
the retention time and one column for another variable such as the area
under the peak or it’s height is required for using
norm_peaks
). All column names within the data frames have
to be the same and named consistently. The attached dataset
peak_data
contains data from skin swabs of Antarctic Fur
Seals Arctocephalus gazella (Stoffel et
al. 2015) and can be used as template.
names(peak_data) # names of individuals, i.e. names of list elements
#> [1] "C3" "C2" "M2" "M3" "M4" "M5" "M6" "M7" "M8" "M9" "M10" "M12"
#> [13] "M14" "M15" "M16" "M17" "M18" "M19" "M20" "M21" "M23" "M24" "M25" "M26"
#> [25] "M27" "M28" "M29" "M30" "M31" "M33" "M35" "M36" "M37" "M38" "M39" "M40"
#> [37] "M41" "M43" "M44" "M45" "M46" "M47" "M48" "P2" "P3" "P4" "P5" "P6"
#> [49] "P7" "P8" "P9" "P10" "P12" "P14" "P15" "P16" "P17" "P18" "P19" "P20"
#> [61] "P21" "P23" "P24" "P25" "P26" "P27" "P28" "P29" "P30" "P31" "P33" "P35"
#> [73] "P36" "P37" "P38" "P39" "P40" "P41" "P43" "P44" "P45" "P46" "P47" "P48"
To check the data formatting for the most common errors, use the
check_input
function. This will test for conformity with
the the main requirements of the aligning algorithm and give a warning
message if these aren’t met. When a text file is used as input, the
decimal has to be a point (not a comma). However, there could
potentially be a variety of different error sources so it is advisable
to make sure by yourself that the data is in the correct format.
# if plot = T, a histogram of peaks is plotted
check_input(data = peak_data,plot = F)
#> All checks passed!
The alignment procedure adjust peaks that represent putatively
homologous substances that differ to varying degree in retention times
among samples. In order to define sensible values for the the parameters
min_diff_peak2peak
it is advisable to investigate how far
peaks are commonly separated within chromatograms. The function
peak_interspace
plots a histogram of all between peak
retention time differences within samples and combines this estimates
for the complete dataset. Here, the difference between close peaks is of
interest and and the function allows to plot certain quantile ranges of
the distribution by specifying the parameter
quantile_range
.
peak_interspace(data = peak_data, rt_col_name = "time",
quantile_range = c(0, 0.8), quantiles = 0.05)
#> $Summary
#> Min. 1st Qu. Median Mean 3rd Qu. Max.
#> 0.0000 0.0600 0.1000 0.2542 0.2500 11.3700
#>
#> $Quantiles
#> 5%
#> 0.03
The histogram shows the distribution of retention-time ‘spaces’
between peaks. Most peaks are around 0.05 minutes apart from each other.
From the distribution we want to infer the potential error-margin around
a peak,that GCalignR will correct. We can see from the histogram that
very few peaks are closer together than 0.03 minutes. By looking at the
original chromatograms it becomes clear that these peaks are usually
substances with low concentration which show a ‘double peak’, i.e. two
peaks appear for what we believe is just a single substance. Therefore,
we decide to take a value of 0.03 for the
min_diff_peak2peak
parameter below. It is noteworthy that
this does not set a strict threshold and substances with a smaller
difference in mean retention times can still be formed during the
alignment (because those peaks are known to exist within samples).
Therefore, we suggest to carefully check the aligned data and revise the
initial peak calling if required.
The core function in GCalignR
is
align_chromatograms
, which will align the peak lists with
the algorithm described above. See ?align_chromatograms
for
a detailed description of the arguments. The alignment process will take
a few minutes to several hours on a standard computer depending on
mainly three factors; (1) the number of samples and (2) the number of
peaks per sample and (3) the number of substances that are classified
during the alignment procedure. Progress bars and run time estimates
(where possible) indicate the progress of the alignment run.
peak_data <- peak_data[1:4] # subset for speed reasons
peak_data_aligned <- align_chromatograms(data = peak_data, # input data
rt_col_name = "time", # retention time variable name
rt_cutoff_low = 15, # remove peaks below 15 Minutes
rt_cutoff_high = 45, # remove peaks exceeding 45 Minutes
reference = NULL, # choose automatically
max_linear_shift = 0.05, # max. shift for linear corrections
max_diff_peak2mean = 0.03, # max. distance of a peak to the mean across samples
min_diff_peak2peak = 0.03, # min. expected distance between peaks
blanks = "C2", # negative control
delete_single_peak = TRUE, # delete peaks that are present in just one sample
write_output = NULL) # add variable names to write aligned data to text files
The aligned data matrices are now stored in data frames which can be accessed as follows:
peak_data_aligned$aligned$time # to access the aligned retention times
peak_data_aligned$aligned$area # to access the aligned area data
The package includes the already aligned data set for all samples using default alignment parameter settings.
The gc_heatmap
function can be used to visualise aligned
datasets. A white filling indicates the absence of a peak in a sample,
when using the default option of a binary heatmap. The basic rationale
of the alignment is to sort the substances with very similar retention
times together, as they represent putatively homologous substances. The
heatmap shows how single peaks for the individuals deviate from the mean
retention time of a substance. As a rule of thumb: The larger the
deviation, the less likely it is the same substance, but retention time
variation can be high for certain peaks. Therefore, retention time
variations are highlighted with respect to mean and outliers are
highlighted. By default, the a threshold value matching the parameter
max_diff_peak2peak
is used to show deviations. However,
deviations might be higher after pairs of rows where merged with respect
to the value of min_diff_peak2peak
. Check out the
documentation with help("gc_heatmap")
for further
possibilities.
The plot function shows a four figure plot for the aligned data. The first histogram shows the number of peaks per sample before and after alignment. The number of peaks is much smaller after the alignment as peaks have been deleted which were present in the control samples, as well as peaks that were found in just a single individual. The histograms on the bottom left shows the full chromatogram shifts (the first step in the algorithm). The bottom middle shows how much peaks vary around their means across samples. The histogram on the bottom right shows how many peaks are shared across samples. In this case, there is just a single substance present in all samples, while often 10-12 samples share a single substance (the mode of the distribution).
Using the print
function, provides a verbal summary of
the alignment procedure is retrieved and the function call can be
retraced.
print(aligned_peak_data)
#> Summary of Peak Alignment running align_chromatograms
#> Input: peak_data
#> Start: 2017-07-19 16:31:47 Finished: 2017-07-19 17:30:47
#>
#> Call:
#> GCalignR::align_chromatograms(data=peak_data, rt_col_name=time,
#> max_linear_shift=0.05, max_diff_peak2mean=0.02, min_diff_peak2peak=0.08,
#> blanks=(C2, C3), delete_single_peak=T, sep=\t, rt_cutoff_low=NULL,
#> rt_cutoff_high=NULL, reference=NULL)
#>
#> Summary of scored substances:
#> total blanks singular retained
#> 494 171 45 278
#>
#> In total 494 substances were identified among all samples. 171 substances were
#> present in blanks. The corresponding peaks as well as the blanks were removed
#> from the data. 45 substances were present in just one single sample and were
#> removed. 278 substances are retained after all filtering steps.
#>
#> Sample overview:
#> The following 84 samples were aligned to the reference 'P20':
#> M2, M3, M4, M5, M6, M7, M8, M9, M10, M12, M14, M15, M16, M17, M18, M19, M20,
#> M21, M23, M24, M25, M26, M27, M28, M29, M30, M31, M33, M35, M36, M37, M38,
#> M39, M40, M41, M43, M44, M45, M46, M47, M48, P2, P3, P4, P5, P6, P7, P8, P9,
#> P10, P12, P14, P15, P16, P17, P18, P19, P20, P21, P23, P24, P25, P26, P27,
#> P28, P29, P30, P31, P33, P35, P36, P37, P38, P39, P40, P41, P43, P44, P45,
#> P46, P47, P48
#>
#> For further details type:
#> 'gc_heatmap(aligned_peak_data)' to retrieve heatmaps
#> 'plot(aligned_peak_data)' to retrieve further diagnostic plots
norm_peaks
is used to standardize the concentration of
peaks across samples to obtain the relative abundance. This is an
essential step prior to the analysis if the absolute concentration of
chemicals varies across samples. Note that this step is also required
when retention time cut-offs, single peak deletion or blank peak removal
was applied, even if the data already contained a measure of relative
abundance. The output is a list of data frames containing the relative
abundance of peaks for every individual.
vegan
offers a variety of useful function for the
analysis of multivariate abundance data such as the scent profiles
handled here. Check out help("vegan")
for a first
overview.
## GCalignR contains factors for the chemical dataset
data("peak_factors")
## keep order of rows consistent
scent <- scent[match(row.names(peak_factors),row.names(scent)),]
## NMDS using Bray-Curtis dissimilarities
scent_nmds <- vegan::metaMDS(comm = scent, distance = "bray")
## get x and y coordinates
scent_nmds <- as.data.frame(scent_nmds[["points"]])
## add the colony as a factor to each sample
scent_nmds <- cbind(scent_nmds,colony = peak_factors[["colony"]])
## ordiplot with ggplot2
library(ggplot2)
ggplot(data = scent_nmds,aes(MDS1,MDS2,color = colony)) +
geom_point() +
theme_void() +
scale_color_manual(values = c("blue","red")) +
theme(panel.background = element_rect(colour = "black", size = 1.25,
fill = NA), aspect.ratio = 1, legend.position = "none")
Update July 2024: vegan::adonis2 is replacing the now defunct function vegan::adonis
Using adonis2 and betadisper we can immediately do multivariate statistics, showing that the two colonies differ significantly. This illustrates a location effect.
## colony effect
vegan::adonis2(scent ~ peak_factors$colony,permutations = 999)
#> Permutation test for adonis under reduced model
#> Terms added sequentially (first to last)
#> Permutation: free
#> Number of permutations: 999
#>
#> vegan::adonis2(formula = scent ~ peak_factors$colony, permutations = 999)
#> Df SumOfSqs R2 F Pr(>F)
#> peak_factors$colony 1 2.543 0.1279 11.733 0.001 ***
#> Residual 80 17.340 0.8721
#> Total 81 19.883 1.0000
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.