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This repository is very specific. It contains a nested dataset of 301 files. Six signals are processed: four uv-vis and a fluorescence signal.

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Introduction

This repository is very specific. It contains a nested dataset extracted from the instrument as .aia files. The batch files contained 301 .aia folders each containing five signals (four uv-vis and a fluorescence signal). These data were generated using scanning gradient in high performance liquid chromatography (HPLC).

Table of contents

Introduction

Data wrangling

Step 1: Create a data frame with all the .aia file folder names and paths

Step 2: Fetch the signal data from each file

Step 3: Fetch the data from each signal file

Step 4: fetch the spectra for each signal into separate data frames

Inspeting the chromatograms

Analysing the data

I started by unnesting the files into workable lists. This can always be improved and accomading to the desired analysis pipeline. This means a total of 1505 spectra processed.

flowchart TD
A[Step 1 <br/> <br/>  A list of 301 .aia files. Each file belongs to a wine sample.] --> |unpack each file| B(Step2 <br/> <br/> signal_1:uv-vis 280nm <br/> signal_2:uv-vis 320nm <br/> signal_3:uv-vis 360nm <br/> signal_4:uv-vis 420nm <br/> signal_5:fluorescence)
B--> C(Step 3 <br/> <br/> Read the data using the ncdf4 library)
C--> |rextract the spectra| D(Step 4 <br/> <br/> spectra = peak retention time vs peak area.)
Loading

Step 1: Create a data frame with all the .aia file folder names and paths

library("tidyverse") # to wrangle data frames
library("glue") 
hplc_wines <-
  data.frame(
    filename = list.files(
      "C:/Users/mafata/Desktop/WORK/Collaborative Work/HPLC scanning/CDF files"
    )
  )
hplc_wines <- hplc_wines  %>%
  mutate(
    filepath = paste0(
      "C:/Users/mafata/Desktop/WORK/Collaborative Work/HPLC scanning/CDF files/",
      filename
    )
  )

Step 2: Fetch the signal data from each file

for (i in 1:length(hplc_wines$filepath)){
  hplc_wines <- hplc_wines  %>%
    mutate(
      samples = str_sub (hplc_wines$filename, end = -8),
      repeats = str_sub (hplc_wines$filename, end = -5),
      uv_280 = paste0(filepath,"/SIGNAL01.cdf"),
      uv_320 = paste0(filepath,"/SIGNAL02.cdf"),
      uv_360 = paste0(filepath,"/SIGNAL03.cdf"),
      uv_420 = paste0(filepath,"/SIGNAL04.cdf"),
      fluo = paste0(filepath,"/SIGNAL05.cdf") # FLD , Ex=280, Em=320
    )
}

Step 3: Fetch the data from each signal file

datasets = c("uv_280","uv_320","uv_360","uv_420","fluo")
for (dataset in datasets){
dataset_list = list()
for (i in 1:length(hplc_wines[[dataset]])){
  dataset_file <- 
    nc_open(
      hplc_wines[[dataset]][i],
      write = FALSE,
      readunlim = FALSE,
      verbose = FALSE,
      auto_GMT = TRUE,
      suppress_dimvals = FALSE,
      return_on_error = FALSE
    )
  dataset_list = append(dataset_list, list(dataset_file))
}
names(dataset_list) = hplc_wines$filename
if (dataset == "uv_280"){uv280_list = dataset_list}
else if (dataset == "uv_320"){uv320_list = dataset_list}
else if (dataset == "uv_360"){uv360_list = dataset_list}
else if (dataset == "uv_420"){uv420_list = dataset_list}
else {fluo_list = dataset_list}
}

Step 4: fetch the spectra for each signal into separate data frames

uv_280_spectra = list()
for (i in 1:length(uv280_list)){
  # Add verbosity to the script
  print(glue(". . . generating sample number {i} uv 280 nm spectra"))
  peak_retention_time <-as.data.frame(ncvar_get(
  uv280_list[[i]],
  uv280_list[[i]]$var$peak_retention_time))
  colnames(peak_retention_time) = "peak_retention_time"
  peak_retention_time <-format(round(peak_retention_time, 0), nsmall = 0)
  peak_area <-as.data.frame(ncvar_get(
  uv280_list[[i]],
  uv280_list[[i]]$var$peak_area))
  colnames(peak_area) = hplc_wines$repeats[i]
  uv_280_spectra <- append(uv_280_spectra,
                              list(name = c(peak_retention_time, peak_area)),
                              after = length(uv_280_spectra))
}
names(uv_280_spectra) = hplc_wines$filename

Then next hurdle is plotting the chromatograms to see if everything is okay inside. It is always good practice to have a look at the spectra to see if there are any funny things going on.

Example overlay spectra for uv_vis 280nm. Example overlay spectra for uv_vis 320nm.
Example overlay spectra for uv_vis 360nm. Example overlay spectra for uv_vis 420nm.
Example overlay fluorescence spectra.

From the previous section we can see that something is up. These are not the expected spectral asthetics. In generating this data set, I extracted it as AIA format. Previously, before I started using scripting language, I generated it as a spectrum of values manually and pain-stakingly copied and pasted into an excel sheet. The values were more frequent than this. The AIA extraction may have been due to my specifications when extracting the data in different formats so I need to find out more about how Agilent instrument data extractions are structured and formated since I suspect it may require peak integration.

Re-wrangling the data from the spreadsheet

The data was pasted as a tuple in seperate columns so we will extract every couple (RT, Abs) and merge them as a naive way to aligning by the retention time.

hplc_wines <-
  readxl::read_excel(path = "/Users/~/HPLC scouting.xlsx",
                     sheet = "280 nm SB") 
uv_280 <- list()
for (i in 1:(ncol(hplc_wines))) {
  first <- as.numeric((2 * i) - 1)
  second <- as.numeric(2 * i)
  sample_i <- hplc_wines[c(first, second)]
  colnames(sample_i)[1] <- c("rt")
  sample_i <- list(sample_i)
  uv_280 <- append(uv_280, sample_i)
}
name_list <-
  row.names(as.data.frame(t(hplc_wines)) %>% filter(row_number() %% 2 == 0))
names(uv_280) <- name_list

# create a merged data frame
merged_uv280_spectra <- full_join(x = as.data.frame(uv_280[[1]]),
                                  y = as.data.frame(uv_280[[2]]),
                                  by = "rt")
for (i in 3:length(uv_280)) {
  merged_uv280_spectra <-
    full_join(
      x = as.data.frame(merged_uv280_spectra),
      y = as.data.frame(uv_280[[i]]),
      by = "rt"
    )
}
merged_uv280_spectra <- merged_uv280_spectra %>%
  pivot_longer(
    !rt,
    names_to = "samples",
    values_to = "peak_area",
    values_drop_na = TRUE
  )

If we compare the previous spectra and the above one we see the differences in the spectral frequecies.

The previous overlay spectra for uv_vis 280nm. New overlay spectra for uv_vis 280nm.

Multiple Factor Analysis (MFA)

Having inspected the new spectra and feeling confident enough about the spectral properties, we can analyse and compare between sample groups using MFA.

mfa_plot <- MFA(
  merged_uv280_spectra[-1],
  group = c(26, 25, 25, 25, 25, 25),
  type = c(rep("s", 6)),
  ncp = 4,
  name.group = c("AVN", "CDB", "DTK", "FRV", "KZN", "PDB"),
  graph = TRUE
)

MFA group representation of the spectra for uv_vis 280nm.

Spectral preprocessing

Although we have managed to obtained a more iconic specrum (baselines are much more resolved, peak symmetry that's more gaussian) we find that there seems to be some misallignments in the peaks and the baseline is slightly ofset among sprectra.

New overlay for the Chenin Blanc uv_vis 280nm. New overlay for fluorescence spectra.

Here we will see what we can do with that.

Coming soon!

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This repository is very specific. It contains a nested dataset of 301 files. Six signals are processed: four uv-vis and a fluorescence signal.

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