Myrio: Myriophyllum model with exponential growth
In cvasi: Calibration, Validation, and Simulation of TKTD Models
View source: R/class-Myriophyllum.R
Myrio R Documentation
Myriophyllum model with exponential growth
Description
The Myriophyllum model is derived from the Lemna TKTD model by
Klein et al. (2021). The Myriophyllum model is mathematically equivalent
to the Tier 2C version of the Lemna model by Klein et al. (2021),
cf. Lemna_SETAC(). Recommended settings for Tier 2C are k_photo_fixed=TRUE
and k_resp=0 (Klein et al. 2021).
In particular, the growth model is a simple exponential growth model,
which is considered to be the typical situation for a laboratory macrophyte
study. Instead of frond numbers as for Lemna, the biomass is also returned as
total shoot length (TSL) in simulation results.
Consequently, the model has the additional parameter r_DW_TSL
(dry weight per total shoot length ratio) instead of r_DW_FN (dry weight
per frond number ratio).
Usage
Myrio()
Value
an S4 object of type MyrioExpScenario
State variables
The model has two state variables:
-
BM, Biomass (g dw m-2 for field studies or mg dw for lab)
-
M_int, Mass of toxicant in plant population (mass per m2, e.g. ug m-2)
Model parameters
Growth model
-
k_photo_max, Maximum photosynthesis rate (d-1), default: 0.47
Concentration response (Toxicodynamics)
-
EC50_int, Internal concentration resulting in 50% effect (ug L-1)
-
E_max, Maximum inhibition (-), default: 1
-
b, Slope parameter (-)
Internal concentration (Toxicokinetics)
-
P, Permeability (cm d-1)
-
r_A_DW, Area per dry-weight ratio (cm2 g-1), default: 1000
-
r_FW_DW, Fresh weight per dry weight ratio (-), default: 16.7
-
r_FW_V, Fresh weight density (g cm-3), default: 1
-
r_DW_TSL, Dry weight per total shoot length ratio (g (field) or mg (lab) dw cm-1)
-
K_pw, Partitioning coefficient plant:water (-), default: 1
-
k_met, Metabolisation rate (d-1), default: 0
Environmental factors
None.
Parameter boundaries
Default values for parameter boundaries are set for all parameters by expert
judgement, for calibration purposes. Values can be modified using set_bounds().
Simulation output
Simulation results will contain two additional columns besides state variables:
-
C_int, internal concentration of toxicant (mass per volume)
-
TSL, total shoot length (?)
The available output levels are as follows:
-
nout >= 1
-
C_int, internal concentration (mass per volume)
-
nout >= 2
-
TSL, total shoot length (?)
-
nout >= 3
-
f_photo, photosynthesis dependency function (-)
-
nout >= 5, growth and TK/TD
-
C_int_unb, unbound internal concentration (mass per volume)
-
C_ext, external concentration (mass per volume)
-
nout >= 7, environmental factors
-
dBM, biomass derivative (g dw m-2 d-1)
-
dM_int, mass of toxicant in plants derivative (mass per m2 d-1)
Effects
Supported effect endpoints include BM (biomass) and r (average
growth rate during simulation). The effect on biomass is calculated from
the last state of a simulation. Be aware that endpoint r is incompatible
with biomass transfers.
Biomass transfer
Models supporting biomass transfer can be instructed to move a fixed amount
of biomass to a new medium after a period of time. This feature replicates
a procedure occurring in e.g. Lemna effect studies and may be necessary to
recreate study results.
The biomass transfer feature assumes that always a fixed amount of
biomass is transferred. Transfers can occur at any fixed point in time or
in regular intervals. During a transfer, the biomass is reset to the
transferred amount and additional compartments can be scaled 1:1 accordingly,
to e.g. reflect the change in internal toxicant mass when biomass is modified.
Transfer settings can be modified using set_transfer().
Any transfer time point must also be an output time point. If a transfer
occurs, simulation results of that time point will report the model state
before the transfer. Be aware that in order to use transfers at regular
intervals, the simulation must start at time point zero.
References
Klein J., Cedergreen N., Heine S., Reichenberger S., Rendal C.,
Schmitt W., Hommen U., 2021: Refined description of the Lemna TKTD growth model
based on Schmitt et al. (2013) - equation system and default parameters.
Report of the working group Lemna of the SETAC Europe Interest Group Effect
Modeling. Version 1, uploaded on 22. Sept. 2021.
https://www.setac.org/group/effect-modeling.html
See Also
Macrophyte-models, Transferable, Scenarios
Other Myriophyllum models:
Myrio_log(),
Myriophyllum-models
Other macrophyte models:
Lemna_SETAC(),
Lemna_Schmitt(),
Macrophyte-models,
Myrio_log()
cvasi documentation built on Sept. 23, 2024, 9:08 a.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
View source: R/class-Myriophyllum.R
| Myrio | R Documentation |
Myriophyllum model with exponential growth
Description
The Myriophyllum model is derived from the Lemna TKTD model by
Klein et al. (2021). The Myriophyllum model is mathematically equivalent
to the Tier 2C version of the Lemna model by Klein et al. (2021),
cf. Lemna_SETAC(). Recommended settings for Tier 2C are k_photo_fixed=TRUE
and k_resp=0 (Klein et al. 2021).
In particular, the growth model is a simple exponential growth model,
which is considered to be the typical situation for a laboratory macrophyte
study. Instead of frond numbers as for Lemna, the biomass is also returned as
total shoot length (TSL) in simulation results.
Consequently, the model has the additional parameter r_DW_TSL
(dry weight per total shoot length ratio) instead of r_DW_FN (dry weight
per frond number ratio).
Usage
Myrio()
Value
an S4 object of type MyrioExpScenario
State variables
The model has two state variables:
-
BM, Biomass (g dw m-2 for field studies or mg dw for lab) -
M_int, Mass of toxicant in plant population (mass per m2, e.g. ug m-2)
Model parameters
Growth model
-
k_photo_max, Maximum photosynthesis rate (d-1), default:0.47
-
Concentration response (Toxicodynamics)
-
EC50_int, Internal concentration resulting in 50% effect (ug L-1) -
E_max, Maximum inhibition (-), default:1 -
b, Slope parameter (-)
-
Internal concentration (Toxicokinetics)
-
P, Permeability (cm d-1) -
r_A_DW, Area per dry-weight ratio (cm2 g-1), default:1000 -
r_FW_DW, Fresh weight per dry weight ratio (-), default:16.7 -
r_FW_V, Fresh weight density (g cm-3), default:1 -
r_DW_TSL, Dry weight per total shoot length ratio (g (field) or mg (lab) dw cm-1) -
K_pw, Partitioning coefficient plant:water (-), default:1 -
k_met, Metabolisation rate (d-1), default:0
-
Environmental factors
None.
Parameter boundaries
Default values for parameter boundaries are set for all parameters by expert
judgement, for calibration purposes. Values can be modified using set_bounds().
Simulation output
Simulation results will contain two additional columns besides state variables:
-
C_int, internal concentration of toxicant (mass per volume) -
TSL, total shoot length (?)
The available output levels are as follows:
-
nout >= 1-
C_int, internal concentration (mass per volume)
-
-
nout >= 2-
TSL, total shoot length (?)
-
-
nout >= 3-
f_photo, photosynthesis dependency function (-)
-
-
nout >= 5, growth and TK/TD-
C_int_unb, unbound internal concentration (mass per volume) -
C_ext, external concentration (mass per volume)
-
-
nout >= 7, environmental factors-
dBM, biomass derivative (g dw m-2 d-1) -
dM_int, mass of toxicant in plants derivative (mass per m2 d-1)
-
Effects
Supported effect endpoints include BM (biomass) and r (average growth rate during simulation). The effect on biomass is calculated from the last state of a simulation. Be aware that endpoint r is incompatible with biomass transfers.
Biomass transfer
Models supporting biomass transfer can be instructed to move a fixed amount of biomass to a new medium after a period of time. This feature replicates a procedure occurring in e.g. Lemna effect studies and may be necessary to recreate study results.
The biomass transfer feature assumes that always a fixed amount of
biomass is transferred. Transfers can occur at any fixed point in time or
in regular intervals. During a transfer, the biomass is reset to the
transferred amount and additional compartments can be scaled 1:1 accordingly,
to e.g. reflect the change in internal toxicant mass when biomass is modified.
Transfer settings can be modified using set_transfer().
Any transfer time point must also be an output time point. If a transfer occurs, simulation results of that time point will report the model state before the transfer. Be aware that in order to use transfers at regular intervals, the simulation must start at time point zero.
References
Klein J., Cedergreen N., Heine S., Reichenberger S., Rendal C., Schmitt W., Hommen U., 2021: Refined description of the Lemna TKTD growth model based on Schmitt et al. (2013) - equation system and default parameters. Report of the working group Lemna of the SETAC Europe Interest Group Effect Modeling. Version 1, uploaded on 22. Sept. 2021. https://www.setac.org/group/effect-modeling.html
See Also
Macrophyte-models, Transferable, Scenarios
Other Myriophyllum models:
Myrio_log(),
Myriophyllum-models
Other macrophyte models:
Lemna_SETAC(),
Lemna_Schmitt(),
Macrophyte-models,
Myrio_log()
R Package Documentation
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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