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This package provides code for estimating the combined toxicity of measured pesticides using their Species Sensitivity Distributions (SSDs) in a multi-substance, potentially affected fraction approach. The resulting value is an estimate of the percentage of species impacted by the measured pesticides, a value which is referred to in this package as the Pesticide Risk Metric (PRM). This is based on the Queensland Department of Environment and Science Water Quality and Investigation’s method (referred to in this package as the WQI Method) used in the Reef 2050 Water Quality Improvement Plan. The main difference is the ability to add different pesticides to be measured provided they have one of the following SSD distributions:
These PRM values can be compared to the three categories of ecosystem condition, as defined in the Australian and New Zealand Guidelines for Fresh & Marine Water Quality seen in the table below.
One of the key functions of this package is the ability to
add your own pesticides to the risk metric, provided that SSD
information is available. This can be done by editing the
pesticide_info
table which is included in this package and
is used as a look-up table for many of the later functions. You can add
pesticides provided you know the SSD distribution type, scale
parameters, shape/location parameters, and weight parameter if required.
Depending on how/if LOR replacement is needed relative LOR replacement
values for each new pesticide will be required, and if the impact of
specific pesticide types is of interest a pesticide type parameter
should be provided. The add_your_own_pesticide()
function
appends new pesticide information to the pesticide_info
table as seen below.
library(CalcThemAll.PRM)
library(DT)
pesticide_info <- CalcThemAll.PRM::pesticide_info #the original 22 pesticides
datatable(pesticide_info, options = list(pageLength = 10,lengthMenu = c(5, 10, 15, 20), scrollX = T))
pesticide_info <- add_your_own_pesticide(pesticides = "Poison", #adding one new pesticide
relative_LORs = 0.023, pesticide_types = "Poison",
distribution_types = "Log-Normal", scales = 0.09,
shape_locations = 0.014)
datatable(pesticide_info, options = list(pageLength = 10,lengthMenu = c(5, 10, 15, 20), scrollX = T))
pesticide_info <- add_your_own_pesticide(pesticides = #adding multiple new pesticides
c("Poison", "Acid", "Sludge"),
relative_LORs = c(0.03, 0.01, 0.5),
pesticide_types = c("Ghost", "Bug", "Poison"),
distribution_types = c("Log-Normal", "Log-Logistic
Log-Logistic", "Burr Type III"),
scales = c(0.3, 0.002, 2),
scale_2s = c(NA, 0.04, NA),
shape_locations = c(1, 0.07, 3),
shape_location_2s = c(NA, 0.14, 2.3),
weights = c(NA, 0.08, NA))
datatable(pesticide_info, options = list(pageLength = 10,lengthMenu = c(5, 10, 15, 20), scrollX = T))
It is not necessary to remove unmeasured pesticides
from the pesticide_info
table due to the independent action
assumption in the methods, however if they are not removed they
will still require an empty column in the concentration data
set and which pesticides are used in the metric should be
clearly documented for transparency.
The treatment of non-detect (left-censored) data is a common issue
for the statistical analysis of lab concentration measurements for risk
assessment or reporting purposes. Environmental monitoring programs such
as those analysing pesticides, metals, or other contaminants, usually
report non detects as being below the analytical limit of reporting
(LOR) of the analysis. Most laboratories report the detection of a
chemical at a concentration less than the LOR of as “< LOR”, for
example “< 0.02 µg/L” if the limit of reporting is 0.02 µg/L. All
that is known about the concentration of such data is that the ‘true’
value must lie somewhere between zero and the LOR. Proper treatment of
such data is imperative for risk assessment, with common approaches
being to report the data at the LOR (simply by removing the “<” sign)
or as a fraction of the LOR (e.g. half or some other fraction). This
package provides two ways to treat LORs using the
treat_LORs_all_data()
function. The first is the method
created by the Department of Environment and Science Queensland Water
Quality Investigations outlined in the methods document above and is
referred to as the “WQI” method. This method looks for
the first above LOR (detect) concentration recorded for each sampling
year or other recurring time interval and replaces every <LOR value
before this with a negligible value of 10^-11. Following the first
detect, it is assumed there is a very small amount of the contaminant in
the waterway, so the <LOR values are replaced with the absolute LOR
(less than sign removed) value multiplied by the relative toxicity value
defined in the pesticide_info
table. This standardizes the
LOR replacement method so that all contaminants are treated equally
according to toxicity; and avoids the introduction of an artificial
toxicity signature. The second method is the replacing all LOR values
with zero and is referred to as the “zero” method. The
treat_LORs_all_data()
function requires a concentration
data set with a column that matches each pesticide name in
the pesticide_info
table and a “Site Name”
and “Date” column, and how to use it can be seen below with the
example Canto_pesticides
concentration data provided in the
package.
datatable(Canto_pesticides, options = list(pageLength = 10,lengthMenu = c(5, 10, 15, 20), scrollX = T)) #Canto pesticide concentrations before LOR treatment
Canto_pesticides_LOR_treated <- treat_LORs_all_data(raw_data = Canto_pesticides, #this is the pesticide concentration data set to be treated
pesticide_info = CalcThemAll.PRM::pesticide_info, #this specifies the pesticide info look-up table
treatment_method = "WQI") #this selects the LOR treatment method
datatable(Canto_pesticides_LOR_treated, options = list(pageLength = 10,lengthMenu = c(5, 10, 15, 20), scrollX = T)) #Canto pesticide concentrations after treatment, LORs should be replaced with either 0.0000001 or LOR replacement value
Once the pesticide_info
table has all the required
pesticides and tbe LOR values have been treated we can begin the
calculating daily average PRM values, the main focus of this
package! The calculate_daily_average_PRM()
function
calculates a daily average PRM value for each day that pesticide
concentration data is provided in a “Total PRM” column. It also
calculates daily average PRM values for each pesticide_type in the
pesticide_info
table in a column named after the type
followed by ” PRM”, for example “PSII Herbicide PRM”. This function is
designed to run with a data frame exported from the
treat_LORs_all_data()
function. However, if you skipped the
treat LORs step the input data frame needs all the same columns and an
additional column for “Sampling Year”. An example of the function is
shown below.
head(Canto_pesticides_LOR_treated) #Canto pesticide concentrations after LOR treatment
#> # A tibble: 6 × 25
#> `Site Name` `Sampling Year` Date Chlorpyrifos Fipronil Pendimethalin
#> <chr> <chr> <chr> <chr> <chr> <chr>
#> 1 Celestial City 2017-2018 2017-07-03 0.00000000001 0.00000… 0.00000000001
#> 2 Celestial City 2017-2018 2017-07-10 <NA> <NA> <NA>
#> 3 Celestial City 2017-2018 2017-07-18 1.892e-08 9.56e-08 2.36e-06
#> 4 Celestial City 2017-2018 2017-07-24 4.73e-08 9.56e-08 2.36e-06
#> 5 Celestial City 2017-2018 2017-07-30 1.892e-08 9.56e-08 2.36e-06
#> 6 Celestial City 2017-2018 2017-08-08 <NA> <NA> <NA>
#> # ℹ 19 more variables: Metolachlor <chr>, MCPA <chr>, Triclopyr <chr>,
#> # Ametryn <chr>, Atrazine <chr>, Prometryn <chr>, Terbuthylazine <chr>,
#> # Simazine <chr>, Diuron <chr>, Imidacloprid <chr>,
#> # `Metsulfuron methyl` <chr>, `2,4-D` <chr>,
#> # `Isoxaflutole metabolite (DKN)` <chr>, Hexazinone <chr>, Metribuzin <chr>,
#> # `Haloxyfop (acid)` <chr>, Imazapic <chr>, Fluroxypyr <chr>,
#> # Tebuthiuron <chr>
#calculate daily PRM
Canto_daily_PRM <- calculate_daily_average_PRM(LOR_treated_data = Canto_pesticides_LOR_treated)
head(Canto_daily_PRM)
#> # A tibble: 6 × 7
#> `Site Name` `Sampling Year` Date `Total PRM` `Insecticide PRM`
#> <chr> <chr> <chr> <dbl> <dbl>
#> 1 Celestial City 2017-2018 2017-07-03 22.9 0.000126
#> 2 Celestial City 2017-2018 2017-07-10 7.34 0.0000172
#> 3 Celestial City 2017-2018 2017-07-18 47.0 0.0145
#> 4 Celestial City 2017-2018 2017-07-24 14.6 0.00851
#> 5 Celestial City 2017-2018 2017-07-30 17.2 0.00533
#> 6 Celestial City 2017-2018 2017-08-08 5.28 0.00000000193
#> # ℹ 2 more variables: `Other Herbicide PRM` <dbl>, `PSII Herbicide PRM` <dbl>
This package also contains a function to plot daily PRM for a
single site and sampling year. plot_daily_PRM()
creates an interactive plotly plot for a single PRM group/type, colour
coded to match the PRM legend table shown at the beginning of this
vignette.
#filter daily PRM data for a single site and sampling year
Violet_Town_2017_2018_PRM <- Canto_daily_PRM %>%
dplyr::filter(.data$`Sampling Year` == "2017-2018" & .data$`Site Name` == "Violet Town")
plot_daily_PRM(daily_PRM_data = Violet_Town_2017_2018_PRM,
title = F, #this toggles the title on and off
wet_season_start = "2017-10-02", #start date of the wet season or high-risk window
#this is optional and can be removed with = NULL
wet_season_length = 182, #length of wet season or high-risk window
PRM_group = "PSII Herbicide PRM") #PRM group to plot, for all PRM = "Total PRM"
This package also contains a function to create a Data Table
colour coded by PRM risk level. PRM_DT()
creates
an interactive data table with the ability to choose if colour is the
cell fill or text.
The final part of this package is for those interested in
estimating a PRM value for a reoccurring large window of time
like a wet season or a period of high pollution risk. It
involves using the calculated daily average PRM values within a wet
season window or high-risk window to generate a single mean value using
multiple imputation to fill in non-sampling days. More
detail about this can be found in the WQI methods document. For example
if looking at wet seasons, if 4 sampling year’s worth of concentration
data is provided there will be a single wet season PRM for each year.
This is done using the calculate_wet_season_average_PRM()
function and at this time is only capable of calculating one
pesticide_type at a time or “Total PRM” being all pesticide groups
together. It is important to note that the multiple imputation method,
like any statistical method, has its own underlying assumptions and
limitations, the primary one being that the observed data are
representative and that there are no unmeasured relationships that are
causing the data to be missing. An example of this would be if a
monitoring program only samples during wet weather events when runoff
and pesticide risk is high. In this example, the multiple imputation
method will replicate this data to fill in missing sampled days, and
thereby the final average will be reflective of wet weather events and
not the entire (low flow and high flow) risk profile. The multiple
imputation approach can still be used, but consideration should be given
to communication of the final average and what it means.
#This calculation can take a few minutes so one site & sampling year is used in this example
Celestial_City_2019_2020_daily_PRM <- Canto_daily_PRM %>%
dplyr::filter(`Site Name` == "Celestial City" & `Sampling Year` == "2019-2020")
CC2019_2020_wet_season_Total_PRM <- calculate_wet_season_average_PRM(daily_PRM_data = Celestial_City_2019_2020_daily_PRM, PRM_group = "Total PRM")
#this calculates the wet season average PRM for all pesticide groups in one total value
#to calculate for a specific group define it in "PRM_group ="
CC2019_2020_wet_season_Total_PRM
#> # A tibble: 1 × 3
#> `Site Name` `Sampling Year` `Total PRM`
#> <chr> <chr> <dbl>
#> 1 Celestial City 2019-2020 26.7
Information is from several sources and, as such, does not necessarily represent government or departmental policy. While every care is taken to ensure the accuracy of this information, the Department of Environment and Science makes no representations or warranties relating to accuracy, reliability, completeness, currency or suitability for any particular purpose and disclaims all responsibility and all liability (including without limitation, liability in negligence) for all expenses, losses, damages (including indirect or consequential damage) and costs that might be incurred as a result of any use or of reliance on the information and calculated data in any way and for any reason.
R Package:
Bezzina A, Neelamraju C, Strauss J, Kaminski H, Roberts C, Glen J, Dias F. 2022. CalcThemAll.PRM: Pesticide Risk Metric Calculations. R package. Water Quality Monitoring & Investigations, Department of Environment and Science, Queensland Government. https://github.com/AlexWaterboyBezzina/CalcThemAll.PRM
Methods Behind Pesticide Risk Metric:
Warne MStJ, Neelamraju C, Strauss J, Smith RA, Turner RDR, Mann RM. 2020. Development of a method for estimating the toxicity of pesticide mixtures and a Pesticide Risk Baseline for the Reef 2050 Water Quality Improvement Plan. Brisbane: Department of Environment and Science, Queensland Government.
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.