using Dates
using Pumas
using PumasUtilities
using CairoMakie
using DataFramesMeta
using CSV
using PharmaDatasets
Covariate Models
Caution
Some functions in this tutorial are only available after you load the PumasUtilities package.
In this tutorial we’ll cover a workflow around covariate model building. You’ll learn how to:
- include covariates in your model
- parse data with covariates
- understand the difference between constant and time-varying covariates
- handle continuous and categorical covariates
- deal with missing data in your covariates
- deal with categorical covariates
1 nlme_sample Dataset
For this tutorial we’ll use the nlme_sample dataset from PharmaDatasets.jl:
pkfile = dataset("nlme_sample", String)
pkdata = CSV.read(pkfile, DataFrame; missingstring = ["NA", ""])
first(pkdata, 5)5×15 DataFrame
| Row | ID | TIME | DV | AMT | EVID | CMT | RATE | WT | AGE | SEX | CRCL | GROUP | ROUTE | DURATION | OCC |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Int64 | Float64 | Float64? | Int64? | Int64 | Int64? | Int64 | Int64 | Int64 | String1 | Int64 | String7 | Float64 | Int64? | Int64 | |
| 1 | 1 | 0.0 | missing | 1000 | 1 | 1 | 500 | 90 | 47 | M | 75 | 1000 mg | Inf | 2 | 1 |
| 2 | 1 | 0.001 | 0.0667231 | missing | 0 | missing | 0 | 90 | 47 | M | 75 | 1000 mg | Inf | missing | 1 |
| 3 | 1 | 1.0 | 112.817 | missing | 0 | missing | 0 | 90 | 47 | M | 75 | 1000 mg | Inf | missing | 1 |
| 4 | 1 | 2.0 | 224.087 | missing | 0 | missing | 0 | 90 | 47 | M | 75 | 1000 mg | Inf | missing | 1 |
| 5 | 1 | 4.0 | 220.047 | missing | 0 | missing | 0 | 90 | 47 | M | 75 | 1000 mg | Inf | missing | 1 |
Note
The nlme_sample dataset has different missing values as the standard datasets in the PharmaDatasets.jl. That’s why we are first getting a String representation of the dataset as a CSV file as pkfile variable. Then, we use it to customize the missingstring keyword argument inside CSV.read function in order to have a working DataFrame for the nlme_sample dataset.
If you want to know more about data wrangling and how to read and write data in different formats, please check out the Data Wrangling Tutorials at tutorials.pumas.ai.
As you can see, the nlme_sample dataset has the standard PK dataset columns such as :ID, :TIME, :DV, :AMT, :EVID and :CMT. The dataset also contains the following list of covariates:
:WT: subject weight in kilograms:SEX: subject sex, either"F"or"M":CRCL: subject creatinine clearance:GROUP: subject dosing group, either"500 mg","750 mg", or"1000 mg"
And we’ll learn how to include them in our Pumas modeling workflows.
describe(pkdata, :mean, :std, :nunique, :first, :last, :eltype)15×7 DataFrame
| Row | variable | mean | std | nunique | first | last | eltype |
|---|---|---|---|---|---|---|---|
| Symbol | Union… | Union… | Union… | Any | Any | Type | |
| 1 | ID | 15.5 | 8.661 | 1 | 30 | Int64 | |
| 2 | TIME | 82.6527 | 63.2187 | 0.0 | 168.0 | Float64 | |
| 3 | DV | 157.315 | 110.393 | missing | missing | Union{Missing, Float64} | |
| 4 | AMT | 750.0 | 204.551 | 1000 | 500 | Union{Missing, Int64} | |
| 5 | EVID | 0.307692 | 0.461835 | 1 | 1 | Int64 | |
| 6 | CMT | 1.0 | 0.0 | 1 | 1 | Union{Missing, Int64} | |
| 7 | RATE | 115.385 | 182.218 | 500 | 250 | Int64 | |
| 8 | WT | 81.6 | 11.6051 | 90 | 96 | Int64 | |
| 9 | AGE | 40.0333 | 11.6479 | 47 | 56 | Int64 | |
| 10 | SEX | 2 | M | F | String1 | ||
| 11 | CRCL | 72.5667 | 26.6212 | 75 | 90 | Int64 | |
| 12 | GROUP | 3 | 1000 mg | 500 mg | String7 | ||
| 13 | ROUTE | Inf | NaN | Inf | Inf | Float64 | |
| 14 | DURATION | 2.0 | 0.0 | 2 | 2 | Union{Missing, Int64} | |
| 15 | OCC | 4.15385 | 2.62836 | 1 | 8 | Int64 |
Tip
As you can see, all these covariates are constant. That means, they do not vary over time. We’ll also cover time-varying covariates later in this tutorial.
2 Step 1 - Parse Data into a Population
The first step in our covariate model building workflow is to parse data into a Population. This is accomplished with the read_pumas function. Here we are to use the covariates keyword argument to pass a vector of column names to be parsed as covariates:
pop = read_pumas(
pkdata;
id = :ID,
time = :TIME,
amt = :AMT,
covariates = [:WT, :AGE, :SEX, :CRCL, :GROUP],
observations = [:DV],
cmt = :CMT,
evid = :EVID,
rate = :RATE,
)Population
Subjects: 30
Covariates: WT, AGE, SEX, CRCL, GROUP
Observations: DVDue to Pumas’ dynamic workflow capabilities, we only need to define our Population once. That is, we tell read_pumas to parse all the covariates available, even if we will be using none or a subset of those in our models.
This is a feature that highly increases workflow efficiency in developing and fitting models.
3 Step 2 - Base Model
The second step of our covariate model building workflow is to develop a base model, i.e., a model without any covariate effects on its parameters. This represents the null model against which covariate models can be tested after checking if covariate inclusion is helpful in our model.
Let’s create a combined-error simple 2-compartment base model:
base_model = @model begin
@param begin
tvcl ∈ RealDomain(; lower = 0)
tvvc ∈ RealDomain(; lower = 0)
tvq ∈ RealDomain(; lower = 0)
tvvp ∈ RealDomain(; lower = 0)
Ω ∈ PDiagDomain(2)
σ_add ∈ RealDomain(; lower = 0)
σ_prop ∈ RealDomain(; lower = 0)
end
@random begin
η ~ MvNormal(Ω)
end
@pre begin
CL = tvcl * exp(η[1])
Vc = tvvc * exp(η[2])
Q = tvq
Vp = tvvp
end
@dynamics Central1Periph1
@derived begin
cp := @. Central / Vc
DV ~ @. Normal(cp, sqrt(cp^2 * σ_prop^2 + σ_add^2))
end
endPumasModel
Parameters: tvcl, tvvc, tvq, tvvp, Ω, σ_add, σ_prop
Random effects: η
Covariates:
Dynamical system variables: Central, Peripheral
Dynamical system type: Closed form
Derived: DV
Observed: DVAnd fit it accordingly:
iparams_base_model = (;
tvvc = 5,
tvcl = 0.02,
tvq = 0.01,
tvvp = 10,
Ω = Diagonal([0.01, 0.01]),
σ_add = 0.1,
σ_prop = 0.1,
)(tvvc = 5,
tvcl = 0.02,
tvq = 0.01,
tvvp = 10,
Ω = [0.01 0.0; 0.0 0.01],
σ_add = 0.1,
σ_prop = 0.1,)fit_base_model = fit(base_model, pop, iparams_base_model, FOCE())[ Info: Checking the initial parameter values. [ Info: The initial negative log likelihood and its gradient are finite. Check passed. Iter Function value Gradient norm 0 8.300164e+03 4.360770e+03 * time: 0.04593396186828613 1 3.110315e+03 9.706222e+02 * time: 1.9061741828918457 2 2.831659e+03 7.817006e+02 * time: 1.9460821151733398 3 2.405281e+03 2.923696e+02 * time: 1.9768011569976807 4 2.370406e+03 3.032286e+02 * time: 1.9993419647216797 5 2.313631e+03 3.126188e+02 * time: 2.022578001022339 6 2.263986e+03 2.946697e+02 * time: 2.0437850952148438 7 2.160182e+03 1.917599e+02 * time: 2.0731520652770996 8 2.112467e+03 1.588288e+02 * time: 2.1554691791534424 9 2.090339e+03 1.108334e+02 * time: 2.17637300491333 10 2.078171e+03 8.108027e+01 * time: 2.198012113571167 11 2.074517e+03 7.813928e+01 * time: 2.2172281742095947 12 2.066270e+03 7.044632e+01 * time: 2.236515998840332 13 2.049660e+03 1.062584e+02 * time: 2.256103038787842 14 2.021965e+03 1.130570e+02 * time: 2.2757561206817627 15 1.994936e+03 7.825801e+01 * time: 2.2952780723571777 16 1.979337e+03 5.318263e+01 * time: 2.315155029296875 17 1.972141e+03 6.807046e+01 * time: 2.368110179901123 18 1.967973e+03 7.896361e+01 * time: 2.388524055480957 19 1.962237e+03 8.343757e+01 * time: 2.408830165863037 20 1.952791e+03 5.565304e+01 * time: 2.4297521114349365 21 1.935857e+03 3.923284e+01 * time: 2.450730085372925 22 1.926254e+03 5.749643e+01 * time: 2.4711790084838867 23 1.922144e+03 4.306225e+01 * time: 2.490638017654419 24 1.911566e+03 4.810496e+01 * time: 2.523993968963623 25 1.906464e+03 4.324267e+01 * time: 2.5450830459594727 26 1.905339e+03 1.207954e+01 * time: 2.5643789768218994 27 1.905092e+03 1.093479e+01 * time: 2.5825321674346924 28 1.904957e+03 1.057034e+01 * time: 2.601018190383911 29 1.904875e+03 1.060882e+01 * time: 2.6301000118255615 30 1.904459e+03 1.031525e+01 * time: 2.648987054824829 31 1.903886e+03 1.041179e+01 * time: 2.6681690216064453 32 1.903313e+03 1.135672e+01 * time: 2.6874771118164062 33 1.903057e+03 1.075683e+01 * time: 2.7059450149536133 34 1.902950e+03 1.091295e+01 * time: 2.7354249954223633 35 1.902887e+03 1.042409e+01 * time: 2.75412917137146 36 1.902640e+03 9.213043e+00 * time: 2.7729949951171875 37 1.902364e+03 9.519321e+00 * time: 2.79206919670105 38 1.902156e+03 5.590984e+00 * time: 2.820669174194336 39 1.902094e+03 1.811898e+00 * time: 2.8395111560821533 40 1.902086e+03 1.644722e+00 * time: 2.858236074447632 41 1.902084e+03 1.653520e+00 * time: 2.876270055770874 42 1.902074e+03 1.720184e+00 * time: 2.9045569896698 43 1.902055e+03 2.619061e+00 * time: 2.9231741428375244 44 1.902015e+03 3.519729e+00 * time: 2.941899061203003 45 1.901962e+03 3.403372e+00 * time: 2.9605581760406494 46 1.901924e+03 1.945644e+00 * time: 2.9891810417175293 47 1.901914e+03 6.273342e-01 * time: 3.007956027984619 48 1.901913e+03 5.374557e-01 * time: 3.026482105255127 49 1.901913e+03 5.710007e-01 * time: 3.0439460277557373 50 1.901913e+03 6.091390e-01 * time: 3.0710220336914062 51 1.901912e+03 6.692417e-01 * time: 3.0890121459960938 52 1.901909e+03 7.579620e-01 * time: 3.1068010330200195 53 1.901903e+03 8.798211e-01 * time: 3.124962091445923 54 1.901889e+03 1.002981e+00 * time: 3.153264045715332 55 1.901864e+03 1.495512e+00 * time: 3.1718859672546387 56 1.901837e+03 1.664621e+00 * time: 3.1899120807647705 57 1.901819e+03 8.601119e-01 * time: 3.207961082458496 58 1.901815e+03 4.525470e-02 * time: 3.235589027404785 59 1.901815e+03 1.294280e-02 * time: 3.2533321380615234 60 1.901815e+03 2.876567e-03 * time: 3.2700130939483643 61 1.901815e+03 2.876567e-03 * time: 3.3175711631774902 62 1.901815e+03 2.876567e-03 * time: 3.3527050018310547
FittedPumasModel
Dynamical system type: Closed form
Number of subjects: 30
Observation records: Active Missing
DV: 540 0
Total: 540 0
Number of parameters: Constant Optimized
0 8
Likelihood approximation: FOCE
Likelihood optimizer: BFGS
Termination Reason: NoObjectiveChange
Log-likelihood value: -1901.815
------------------
Estimate
------------------
tvcl 0.1542
tvvc 4.5856
tvq 0.042341
tvvp 3.7082
Ω₁,₁ 0.26467
Ω₂,₂ 0.10627
σ_add 0.032183
σ_prop 0.061005
------------------4 Step 3 - Covariate Model
The third step of our covariate model building workflow is to actually develop one or more covariate models. Let’s develop three covariate models:
- allometric scaling based on weight
- clearance effect based on creatinine clearance
- separated error model based on sex
To include covariates in a Pumas model we need to first include them in the @covariates block. Then, we are free to use them inside the @pre block
Here’s our covariate model with allometric scaling based on weight:
Tip
When building covariate models, unlike in NONMEM, it is highly recommended to derive covariates or perform any required transformations or scaling as a data wrangling step and pass the derived/transformed into read_pumas as a covariate. In this particular case, it is easy to create two columns in the original data as:
@rtransform! pkdata :ASWT_CL = (:WT / 70)^0.75
@rtransform! pkdata :ASWT_Vc = (:WT / 70)Then, you bring these covariates into read_pumas and use them directly on CL and Vc. This will avoid computations of your transformations during the model fit.
covariate_model_wt = @model begin
@param begin
tvcl ∈ RealDomain(; lower = 0)
tvvc ∈ RealDomain(; lower = 0)
tvq ∈ RealDomain(; lower = 0)
tvvp ∈ RealDomain(; lower = 0)
Ω ∈ PDiagDomain(2)
σ_add ∈ RealDomain(; lower = 0)
σ_prop ∈ RealDomain(; lower = 0)
end
@random begin
η ~ MvNormal(Ω)
end
@covariates begin
WT
end
@pre begin
CL = tvcl * (WT / 70)^0.75 * exp(η[1])
Vc = tvvc * (WT / 70) * exp(η[2])
Q = tvq
Vp = tvvp
end
@dynamics Central1Periph1
@derived begin
cp := @. Central / Vc
DV ~ @. Normal(cp, sqrt(cp^2 * σ_prop^2 + σ_add^2))
end
endPumasModel
Parameters: tvcl, tvvc, tvq, tvvp, Ω, σ_add, σ_prop
Random effects: η
Covariates: WT
Dynamical system variables: Central, Peripheral
Dynamical system type: Closed form
Derived: DV
Observed: DVOnce we included the WT covariate in the @covariates block we can use the WT values inside the @pre block. For both clearance (CL) and volume of the central compartment (Vc), we are allometric scaling by the WT value by the mean weight 70 and, in the case of CL using an allometric exponent with value 0.75.
Let’s fit our covariate_model_wt. Notice that we have not added any new parameters inside the @param block, thus, we can use the same iparams_base_model initial parameters values’ list:
fit_covariate_model_wt = fit(covariate_model_wt, pop, iparams_base_model, FOCE())[ Info: Checking the initial parameter values. [ Info: The initial negative log likelihood and its gradient are finite. Check passed. Iter Function value Gradient norm 0 7.695401e+03 4.898919e+03 * time: 2.384185791015625e-5 1 2.846050e+03 1.128657e+03 * time: 0.5385689735412598 2 2.472982e+03 7.008264e+02 * time: 0.6559848785400391 3 2.180690e+03 2.312704e+02 * time: 0.6808948516845703 4 2.125801e+03 1.862929e+02 * time: 0.7026798725128174 5 2.103173e+03 1.320946e+02 * time: 0.7238888740539551 6 2.091136e+03 1.103035e+02 * time: 0.7441959381103516 7 2.081443e+03 1.091133e+02 * time: 0.7636978626251221 8 2.071793e+03 7.197675e+01 * time: 0.7837240695953369 9 2.062706e+03 7.623310e+01 * time: 0.8381810188293457 10 2.057515e+03 6.885476e+01 * time: 0.8587050437927246 11 2.051133e+03 6.368504e+01 * time: 0.8782858848571777 12 2.038626e+03 7.730243e+01 * time: 0.8979129791259766 13 2.019352e+03 1.136864e+02 * time: 0.9178669452667236 14 1.997136e+03 1.005748e+02 * time: 0.9378490447998047 15 1.983023e+03 6.831478e+01 * time: 0.9709649085998535 16 1.977700e+03 5.649783e+01 * time: 0.9914679527282715 17 1.974583e+03 6.357642e+01 * time: 1.0115289688110352 18 1.967292e+03 7.658974e+01 * time: 1.032456874847412 19 1.951045e+03 6.130573e+01 * time: 1.0556640625 20 1.935868e+03 4.845839e+01 * time: 1.0878279209136963 21 1.929356e+03 6.325782e+01 * time: 1.1098530292510986 22 1.925187e+03 3.142245e+01 * time: 1.1301639080047607 23 1.923733e+03 4.623400e+01 * time: 1.1500270366668701 24 1.918498e+03 5.347738e+01 * time: 1.1806020736694336 25 1.912383e+03 5.849125e+01 * time: 1.2030160427093506 26 1.905510e+03 3.254038e+01 * time: 1.2247228622436523 27 1.903629e+03 2.905618e+01 * time: 1.2547860145568848 28 1.902833e+03 2.907696e+01 * time: 1.2750270366668701 29 1.902447e+03 2.746037e+01 * time: 1.2941889762878418 30 1.899399e+03 1.930949e+01 * time: 1.3145909309387207 31 1.898705e+03 1.186361e+01 * time: 1.3447389602661133 32 1.898505e+03 1.050402e+01 * time: 1.3646018505096436 33 1.898474e+03 1.042186e+01 * time: 1.382849931716919 34 1.897992e+03 1.238729e+01 * time: 1.4015629291534424 35 1.897498e+03 1.729368e+01 * time: 1.430527925491333 36 1.896954e+03 1.472554e+01 * time: 1.4500210285186768 37 1.896744e+03 5.852824e+00 * time: 1.4691429138183594 38 1.896705e+03 1.171353e+00 * time: 1.4868528842926025 39 1.896704e+03 1.216117e+00 * time: 1.515204906463623 40 1.896703e+03 1.230336e+00 * time: 1.5335350036621094 41 1.896698e+03 1.250715e+00 * time: 1.5519840717315674 42 1.896688e+03 1.449552e+00 * time: 1.5702450275421143 43 1.896666e+03 2.533300e+00 * time: 1.5988290309906006 44 1.896631e+03 3.075536e+00 * time: 1.6176040172576904 45 1.896599e+03 2.139797e+00 * time: 1.6363379955291748 46 1.896587e+03 6.636030e-01 * time: 1.6550359725952148 47 1.896585e+03 6.303517e-01 * time: 1.68361496925354 48 1.896585e+03 5.995265e-01 * time: 1.7016799449920654 49 1.896584e+03 5.844159e-01 * time: 1.7196369171142578 50 1.896583e+03 6.083858e-01 * time: 1.737612009048462 51 1.896579e+03 8.145327e-01 * time: 1.7656750679016113 52 1.896570e+03 1.293490e+00 * time: 1.7845509052276611 53 1.896549e+03 1.877705e+00 * time: 1.8031020164489746 54 1.896513e+03 2.217392e+00 * time: 1.8215129375457764 55 1.896482e+03 1.658148e+00 * time: 1.8497788906097412 56 1.896466e+03 5.207217e-01 * time: 1.8683269023895264 57 1.896463e+03 1.177468e-01 * time: 1.8866899013519287 58 1.896463e+03 1.678937e-02 * time: 1.9039969444274902 59 1.896463e+03 2.666635e-03 * time: 1.930351972579956 60 1.896463e+03 2.666635e-03 * time: 1.9652109146118164 61 1.896463e+03 2.666635e-03 * time: 1.9920899868011475
FittedPumasModel
Dynamical system type: Closed form
Number of subjects: 30
Observation records: Active Missing
DV: 540 0
Total: 540 0
Number of parameters: Constant Optimized
0 8
Likelihood approximation: FOCE
Likelihood optimizer: BFGS
Termination Reason: NoXChange
Log-likelihood value: -1896.4632
------------------
Estimate
------------------
tvcl 0.13915
tvvc 3.9754
tvq 0.041988
tvvp 3.5722
Ω₁,₁ 0.23874
Ω₂,₂ 0.081371
σ_add 0.032174
σ_prop 0.061012
------------------We can definitely see that, despite not increasing the parameters of the model, our loglikelihood is higher (implying lower objective function value). Furthermore, our additive and combined error values remain almost the same while our Ωs decreased for CL and Vc. This implies that the WT covariate is definitely assisting in a better model fit by capturing the variability in CL and Vc. We’ll compare models in the next step.
Let’s now try to incorporate into this model creatinine clearance (CRCL) effect on clearance (CL):
Tip
Like the tip above, you can derive covariates or perform any required transformations or scaling as a data wrangling step and pass the derived/transformed into read_pumas as a covariate. In this particular case, it is easy to create three more columns in the original data as:
@rtransform! pkdata :CRCL_CL = :CRCL / 100
@rtransform! pkdata :ASWT_CL = (:WT / 70)^0.75
@rtransform! pkdata :ASWT_Vc = (:WT / 70)Then, you bring these covariates into read_pumas and use them directly on renCL, CL and Vc. This will avoid computations of your transformations during the model fit.
covariate_model_wt_crcl = @model begin
@param begin
tvvc ∈ RealDomain(; lower = 0)
tvq ∈ RealDomain(; lower = 0)
tvvp ∈ RealDomain(; lower = 0)
tvcl_hep ∈ RealDomain(; lower = 0)
tvcl_ren ∈ RealDomain(; lower = 0)
Ω ∈ PDiagDomain(2)
σ_add ∈ RealDomain(; lower = 0)
σ_prop ∈ RealDomain(; lower = 0)
dCRCL ∈ RealDomain()
end
@random begin
η ~ MvNormal(Ω)
end
@covariates begin
WT
CRCL
end
@pre begin
hepCL = tvcl_hep * (WT / 70)^0.75
renCL = tvcl_ren * (CRCL / 100)^dCRCL
CL = (hepCL + renCL) * exp(η[1])
Vc = tvvc * (WT / 70) * exp(η[2])
Q = tvq
Vp = tvvp
end
@dynamics Central1Periph1
@derived begin
cp := @. Central / Vc
DV ~ @. Normal(cp, sqrt(cp^2 * σ_prop^2 + σ_add^2))
end
endPumasModel
Parameters: tvvc, tvq, tvvp, tvcl_hep, tvcl_ren, Ω, σ_add, σ_prop, dCRCL
Random effects: η
Covariates: WT, CRCL
Dynamical system variables: Central, Peripheral
Dynamical system type: Closed form
Derived: DV
Observed: DVIn the covariate_model_wt_crcl model we are keeping our allometric scaling on WT from before. But we are also adding a new covariate creatinine clearance (CRCL), dividing clearance (CL) into hepatic (hepCL) and renal clearance (renCL), along with a new parameter dCRCL.
dCRCL is the exponent of the power function for the effect of creatinine clearance on renal clearance. In some models this parameter is fixed, however we’ll allow the model to estimate it.
This is a good example on how to add covariate coefficients such as dCRCL in any Pumas covariate model. Now, let’s fit this model. Note that we need a new initial parameters values’ list since the previous one we used doesn’t include dCRCL, tvcl_hep or tvcl_ren:
iparams_covariate_model_wt_crcl = (;
tvvc = 5,
tvcl_hep = 0.01,
tvcl_ren = 0.01,
tvq = 0.01,
tvvp = 10,
Ω = Diagonal([0.01, 0.01]),
σ_add = 0.1,
σ_prop = 0.1,
dCRCL = 0.9,
)(tvvc = 5,
tvcl_hep = 0.01,
tvcl_ren = 0.01,
tvq = 0.01,
tvvp = 10,
Ω = [0.01 0.0; 0.0 0.01],
σ_add = 0.1,
σ_prop = 0.1,
dCRCL = 0.9,)fit_covariate_model_wt_crcl =
fit(covariate_model_wt_crcl, pop, iparams_covariate_model_wt_crcl, FOCE())[ Info: Checking the initial parameter values. [ Info: The initial negative log likelihood and its gradient are finite. Check passed. Iter Function value Gradient norm 0 8.554152e+03 5.650279e+03 * time: 3.695487976074219e-5 1 3.572050e+03 1.302046e+03 * time: 0.7907719612121582 2 3.266947e+03 5.384244e+02 * time: 1.0262470245361328 3 3.150635e+03 1.918079e+02 * time: 1.055945873260498 4 3.108122e+03 1.277799e+02 * time: 1.083669900894165 5 3.091358e+03 8.838080e+01 * time: 1.1098239421844482 6 3.082997e+03 8.321689e+01 * time: 1.1364469528198242 7 3.076379e+03 8.167702e+01 * time: 1.1626908779144287 8 3.067422e+03 1.177822e+02 * time: 1.1903748512268066 9 3.048580e+03 2.526969e+02 * time: 1.2786378860473633 10 2.993096e+03 6.325396e+02 * time: 1.3217649459838867 11 2.965744e+03 7.634718e+02 * time: 1.3999059200286865 12 2.921212e+03 9.704020e+02 * time: 1.4477999210357666 13 2.553649e+03 6.642510e+02 * time: 1.504417896270752 14 2.319495e+03 3.204711e+02 * time: 1.5618150234222412 15 2.183040e+03 2.174905e+02 * time: 1.606086015701294 16 2.157621e+03 3.150983e+02 * time: 1.633354902267456 17 2.132395e+03 2.847614e+02 * time: 1.67510986328125 18 2.084799e+03 1.563370e+02 * time: 1.7030329704284668 19 2.071497e+03 1.006429e+02 * time: 1.7289249897003174 20 2.064983e+03 9.753313e+01 * time: 1.754338026046753 21 2.048289e+03 9.230405e+01 * time: 1.7929918766021729 22 2.020938e+03 1.292359e+02 * time: 1.8195610046386719 23 1.983888e+03 2.284990e+02 * time: 1.8468818664550781 24 1.962132e+03 1.220188e+02 * time: 1.87260103225708 25 1.945947e+03 1.035894e+02 * time: 1.9090468883514404 26 1.917782e+03 8.246698e+01 * time: 1.9356598854064941 27 1.905967e+03 5.408054e+01 * time: 1.9621219635009766 28 1.898569e+03 2.172222e+01 * time: 1.9993810653686523 29 1.897473e+03 1.689350e+01 * time: 2.0248069763183594 30 1.897019e+03 1.666689e+01 * time: 2.049522876739502 31 1.896796e+03 1.699751e+01 * time: 2.0847270488739014 32 1.896559e+03 1.645900e+01 * time: 2.110153913497925 33 1.896223e+03 1.415504e+01 * time: 2.134842872619629 34 1.895773e+03 1.630081e+01 * time: 2.16812801361084 35 1.895309e+03 1.723930e+01 * time: 2.191890001296997 36 1.895004e+03 1.229983e+01 * time: 2.2155280113220215 37 1.894871e+03 5.385102e+00 * time: 2.2386488914489746 38 1.894827e+03 3.465463e+00 * time: 2.272165060043335 39 1.894816e+03 3.387474e+00 * time: 2.2950658798217773 40 1.894807e+03 3.295388e+00 * time: 2.3171470165252686 41 1.894786e+03 3.089194e+00 * time: 2.3496038913726807 42 1.894737e+03 2.928080e+00 * time: 2.371971845626831 43 1.894624e+03 3.088723e+00 * time: 2.3944320678710938 44 1.894413e+03 3.493791e+00 * time: 2.4268798828125 45 1.894127e+03 3.142865e+00 * time: 2.4501750469207764 46 1.893933e+03 2.145253e+00 * time: 2.4729180335998535 47 1.893888e+03 2.172800e+00 * time: 2.495419979095459 48 1.893880e+03 2.180509e+00 * time: 2.528125047683716 49 1.893876e+03 2.134257e+00 * time: 2.5501489639282227 50 1.893868e+03 2.032354e+00 * time: 2.572143077850342 51 1.893846e+03 1.760874e+00 * time: 2.604569911956787 52 1.893796e+03 1.779016e+00 * time: 2.6273109912872314 53 1.893694e+03 2.018956e+00 * time: 2.6500909328460693 54 1.893559e+03 2.366854e+00 * time: 2.6823549270629883 55 1.893474e+03 3.690142e+00 * time: 2.7051680088043213 56 1.893446e+03 3.675109e+00 * time: 2.727540969848633 57 1.893439e+03 3.426419e+00 * time: 2.7487540245056152 58 1.893429e+03 3.183164e+00 * time: 2.7806448936462402 59 1.893398e+03 2.695171e+00 * time: 2.8034799098968506 60 1.893328e+03 2.753548e+00 * time: 2.826385974884033 61 1.893169e+03 3.589748e+00 * time: 2.8604068756103516 62 1.892920e+03 3.680718e+00 * time: 2.883957862854004 63 1.892667e+03 2.568107e+00 * time: 2.906899929046631 64 1.892514e+03 1.087910e+00 * time: 2.9419338703155518 65 1.892493e+03 3.287296e-01 * time: 2.966784954071045 66 1.892492e+03 2.967465e-01 * time: 2.989466905593872 67 1.892492e+03 3.020682e-01 * time: 3.011033058166504 68 1.892491e+03 3.034704e-01 * time: 3.0428829193115234 69 1.892491e+03 3.091846e-01 * time: 3.0647499561309814 70 1.892491e+03 3.224170e-01 * time: 3.0860040187835693 71 1.892490e+03 6.494197e-01 * time: 3.1179280281066895 72 1.892488e+03 1.115188e+00 * time: 3.1401939392089844 73 1.892483e+03 1.838833e+00 * time: 3.162276029586792 74 1.892472e+03 2.765371e+00 * time: 3.184556007385254 75 1.892452e+03 3.463807e+00 * time: 3.217589855194092 76 1.892431e+03 2.805270e+00 * time: 3.240056037902832 77 1.892411e+03 5.758916e-01 * time: 3.262515068054199 78 1.892410e+03 1.434041e-01 * time: 3.295076847076416 79 1.892409e+03 1.639246e-01 * time: 3.3179469108581543 80 1.892409e+03 1.145856e-01 * time: 3.3397669792175293 81 1.892409e+03 3.966861e-02 * time: 3.370898962020874 82 1.892409e+03 3.550808e-02 * time: 3.3920600414276123 83 1.892409e+03 3.456241e-02 * time: 3.412559986114502 84 1.892409e+03 3.114018e-02 * time: 3.433134078979492 85 1.892409e+03 4.080806e-02 * time: 3.464169979095459 86 1.892409e+03 6.722726e-02 * time: 3.485511064529419 87 1.892409e+03 1.006791e-01 * time: 3.506422996520996 88 1.892409e+03 1.303988e-01 * time: 3.5376529693603516 89 1.892409e+03 1.228919e-01 * time: 3.5587570667266846 90 1.892409e+03 6.433813e-02 * time: 3.57991099357605 91 1.892409e+03 1.314164e-02 * time: 3.6008970737457275 92 1.892409e+03 4.929931e-04 * time: 3.631732940673828
FittedPumasModel
Dynamical system type: Closed form
Number of subjects: 30
Observation records: Active Missing
DV: 540 0
Total: 540 0
Number of parameters: Constant Optimized
0 10
Likelihood approximation: FOCE
Likelihood optimizer: BFGS
Termination Reason: GradientNorm
Log-likelihood value: -1892.409
--------------------
Estimate
--------------------
tvvc 3.9757
tvq 0.042177
tvvp 3.6434
tvcl_hep 0.058572
tvcl_ren 0.1337
Ω₁,₁ 0.18299
Ω₂,₂ 0.081353
σ_add 0.032174
σ_prop 0.06101
dCRCL 1.1331
--------------------As before, our loglikelihood is higher (implying lower objective function value). Furthermore, our additive and combined error values remain almost the same while our Ω on CL, Ω₁,₁, decreased. This implies that the CRCL covariate with an estimated exponent dCRCL is definitely assisting in a better model fit.
Finally let’s include a separated CL model based on sex as a third covariate model:
covariate_model_wt_crcl_sex = @model begin
@param begin
tvvc ∈ RealDomain(; lower = 0)
tvq ∈ RealDomain(; lower = 0)
tvvp ∈ RealDomain(; lower = 0)
tvcl_hep_M ∈ RealDomain(; lower = 0)
tvcl_hep_F ∈ RealDomain(; lower = 0)
tvcl_ren_M ∈ RealDomain(; lower = 0)
tvcl_ren_F ∈ RealDomain(; lower = 0)
Ω ∈ PDiagDomain(2)
σ_add ∈ RealDomain(; lower = 0)
σ_prop ∈ RealDomain(; lower = 0)
dCRCL_M ∈ RealDomain()
dCRCL_F ∈ RealDomain()
end
@random begin
η ~ MvNormal(Ω)
end
@covariates begin
WT
CRCL
SEX
end
@pre begin
tvcl_hep = ifelse(SEX == "M", tvcl_hep_M, tvcl_hep_F)
tvcl_ren = ifelse(SEX == "M", tvcl_ren_M, tvcl_ren_F)
dCRCL = ifelse(SEX == "M", dCRCL_M, dCRCL_F)
hepCL = tvcl_hep * (WT / 70)^0.75
renCL = tvcl_ren * (CRCL / 100)^dCRCL
CL = (hepCL + renCL) * exp(η[1])
Vc = tvvc * (WT / 70) * exp(η[2])
Q = tvq
Vp = tvvp
end
@dynamics Central1Periph1
@derived begin
cp := @. Central / Vc
DV ~ @. Normal(cp, sqrt(cp^2 * σ_prop^2 + σ_add^2))
end
endPumasModel
Parameters: tvvc, tvq, tvvp, tvcl_hep_M, tvcl_hep_F, tvcl_ren_M, tvcl_ren_F, Ω, σ_add, σ_prop, dCRCL_M, dCRCL_F
Random effects: η
Covariates: WT, CRCL, SEX
Dynamical system variables: Central, Peripheral
Dynamical system type: Closed form
Derived: DV
Observed: DVIn the covariate_model_wt_crcl_sex model we are keeping our allometric scaling on WT, the CRCL effect on renCL, and the breakdown of CL into hepCL and renCL from before. However we are separating them with different values by sex. Hence, we have a new covariate SEX and six new parameters in the @param block by expanding tvcl_hep, tvcl_ren, and dCRCL into male (suffix M) and female (suffix F).
This is a good example on how to add create binary values based on covariate values such as SEX inside the @pre block with the ifelse function. Now, let’s fit this model. Note that we need a new initial parameters values’ list since the previous one we used had a single tvcl_hep, tvcl_ren, and dCRCL:
iparams_covariate_model_wt_crcl_sex = (;
tvvc = 5,
tvcl_hep_M = 0.01,
tvcl_hep_F = 0.01,
tvcl_ren_M = 0.01,
tvcl_ren_F = 0.01,
tvq = 0.01,
tvvp = 10,
Ω = Diagonal([0.01, 0.01]),
σ_add = 0.1,
σ_prop = 0.1,
dCRCL_M = 0.9,
dCRCL_F = 0.9,
)(tvvc = 5,
tvcl_hep_M = 0.01,
tvcl_hep_F = 0.01,
tvcl_ren_M = 0.01,
tvcl_ren_F = 0.01,
tvq = 0.01,
tvvp = 10,
Ω = [0.01 0.0; 0.0 0.01],
σ_add = 0.1,
σ_prop = 0.1,
dCRCL_M = 0.9,
dCRCL_F = 0.9,)fit_covariate_model_wt_crcl_sex =
fit(covariate_model_wt_crcl_sex, pop, iparams_covariate_model_wt_crcl_sex, FOCE())[ Info: Checking the initial parameter values. [ Info: The initial negative log likelihood and its gradient are finite. Check passed. Iter Function value Gradient norm 0 8.554152e+03 5.650279e+03 * time: 1.5020370483398438e-5 1 3.641387e+03 1.432080e+03 * time: 0.5748898983001709 2 3.290450e+03 5.274782e+02 * time: 0.6103770732879639 3 3.185512e+03 2.173676e+02 * time: 0.6424679756164551 4 3.143009e+03 1.479653e+02 * time: 0.8500308990478516 5 3.128511e+03 8.980031e+01 * time: 0.8791029453277588 6 3.123188e+03 5.033125e+01 * time: 0.9088430404663086 7 3.120794e+03 4.279722e+01 * time: 0.9379138946533203 8 3.118627e+03 3.971051e+01 * time: 0.9672050476074219 9 3.115300e+03 8.456587e+01 * time: 0.9967479705810547 10 3.109353e+03 1.350354e+02 * time: 1.0273690223693848 11 3.095894e+03 1.998258e+02 * time: 1.4164199829101562 12 2.988214e+03 4.366433e+02 * time: 1.4634170532226562 13 2.896081e+03 5.505943e+02 * time: 1.568173885345459 14 2.652467e+03 7.300323e+02 * time: 3.3959848880767822 15 2.560937e+03 6.973661e+02 * time: 3.538709878921509 16 2.254941e+03 2.740033e+02 * time: 3.620448112487793 17 2.222509e+03 2.034303e+02 * time: 3.6524150371551514 18 2.171255e+03 2.449580e+02 * time: 3.6836330890655518 19 2.024532e+03 1.121511e+02 * time: 3.713408946990967 20 1.993723e+03 1.042814e+02 * time: 3.741520881652832 21 1.985113e+03 8.079014e+01 * time: 3.7687458992004395 22 1.976757e+03 7.054196e+01 * time: 3.7956950664520264 23 1.969970e+03 6.070322e+01 * time: 3.8226358890533447 24 1.961095e+03 6.810782e+01 * time: 3.8528048992156982 25 1.947983e+03 8.116920e+01 * time: 3.8855741024017334 26 1.930371e+03 8.530051e+01 * time: 3.9367198944091797 27 1.910209e+03 6.993170e+01 * time: 3.965648889541626 28 1.899107e+03 3.362640e+01 * time: 3.9943079948425293 29 1.898022e+03 2.642220e+01 * time: 4.021176099777222 30 1.897055e+03 1.213144e+01 * time: 4.048240900039673 31 1.896596e+03 7.773239e+00 * time: 4.075054883956909 32 1.896538e+03 7.997039e+00 * time: 4.101284027099609 33 1.896451e+03 8.160909e+00 * time: 4.12702488899231 34 1.896283e+03 8.237721e+00 * time: 4.152663946151733 35 1.895903e+03 1.520219e+01 * time: 4.195198059082031 36 1.895272e+03 2.358916e+01 * time: 4.222898960113525 37 1.894536e+03 2.461296e+01 * time: 4.251069068908691 38 1.893995e+03 1.546128e+01 * time: 4.278095006942749 39 1.893858e+03 6.976137e+00 * time: 4.304495096206665 40 1.893833e+03 6.019466e+00 * time: 4.329987049102783 41 1.893786e+03 3.827201e+00 * time: 4.355616092681885 42 1.893714e+03 3.323412e+00 * time: 4.397566080093384 43 1.893592e+03 3.215150e+00 * time: 4.424911975860596 44 1.893435e+03 6.534965e+00 * time: 4.451607942581177 45 1.893286e+03 7.424154e+00 * time: 4.478426933288574 46 1.893190e+03 5.552627e+00 * time: 4.504862070083618 47 1.893139e+03 3.222316e+00 * time: 4.543848991394043 48 1.893120e+03 3.015339e+00 * time: 4.569974899291992 49 1.893107e+03 3.244809e+00 * time: 4.596102952957153 50 1.893080e+03 6.163100e+00 * time: 4.621737957000732 51 1.893027e+03 9.824713e+00 * time: 4.648016929626465 52 1.892912e+03 1.390100e+01 * time: 4.68916392326355 53 1.892734e+03 1.510937e+01 * time: 4.717516899108887 54 1.892561e+03 1.008563e+01 * time: 4.744771957397461 55 1.892485e+03 3.730668e+00 * time: 4.771629095077515 56 1.892471e+03 3.380261e+00 * time: 4.808803081512451 57 1.892463e+03 3.167904e+00 * time: 4.834775924682617 58 1.892441e+03 4.152065e+00 * time: 4.860971927642822 59 1.892391e+03 7.355996e+00 * time: 4.903656005859375 60 1.892268e+03 1.195397e+01 * time: 4.945604085922241 61 1.892026e+03 1.640783e+01 * time: 4.999799013137817 62 1.891735e+03 1.593576e+01 * time: 5.032012939453125 63 1.891569e+03 8.316423e+00 * time: 5.057825088500977 64 1.891494e+03 3.948212e+00 * time: 5.094204902648926 65 1.891481e+03 3.911593e+00 * time: 5.121423959732056 66 1.891457e+03 3.875559e+00 * time: 5.148003101348877 67 1.891405e+03 3.811247e+00 * time: 5.184107065200806 68 1.891262e+03 3.657045e+00 * time: 5.210493087768555 69 1.890930e+03 4.957405e+00 * time: 5.246721982955933 70 1.890317e+03 6.657726e+00 * time: 5.273772954940796 71 1.889660e+03 6.086302e+00 * time: 5.3006439208984375 72 1.889303e+03 2.270929e+00 * time: 5.337035894393921 73 1.889253e+03 7.695301e-01 * time: 5.363384962081909 74 1.889252e+03 7.382144e-01 * time: 5.388885021209717 75 1.889251e+03 7.187898e-01 * time: 5.4250168800354 76 1.889251e+03 7.215047e-01 * time: 5.449865102767944 77 1.889250e+03 7.235155e-01 * time: 5.4845709800720215 78 1.889249e+03 7.246818e-01 * time: 5.510447978973389 79 1.889244e+03 7.257796e-01 * time: 5.536461114883423 80 1.889233e+03 7.198190e-01 * time: 5.5738489627838135 81 1.889204e+03 1.089029e+00 * time: 5.6005189418792725 82 1.889142e+03 1.801601e+00 * time: 5.636109113693237 83 1.889043e+03 2.967917e+00 * time: 5.662697076797485 84 1.888889e+03 2.965856e+00 * time: 5.689665079116821 85 1.888705e+03 5.933555e-01 * time: 5.726285934448242 86 1.888655e+03 9.577698e-01 * time: 5.752593040466309 87 1.888582e+03 1.498494e+00 * time: 5.778956890106201 88 1.888533e+03 1.502751e+00 * time: 5.815237045288086 89 1.888490e+03 1.184664e+00 * time: 5.842037916183472 90 1.888480e+03 6.684515e-01 * time: 5.8782970905303955 91 1.888476e+03 3.680032e-01 * time: 5.904489040374756 92 1.888476e+03 4.720040e-01 * time: 5.930001974105835 93 1.888476e+03 4.768646e-01 * time: 5.96504807472229 94 1.888475e+03 4.736674e-01 * time: 5.990714073181152 95 1.888475e+03 4.552765e-01 * time: 6.016721963882446 96 1.888474e+03 5.193725e-01 * time: 6.052011013031006 97 1.888473e+03 8.850098e-01 * time: 6.077670097351074 98 1.888468e+03 1.461598e+00 * time: 6.112586975097656 99 1.888458e+03 2.209124e+00 * time: 6.138339996337891 100 1.888437e+03 2.961236e+00 * time: 6.164604902267456 101 1.888407e+03 2.978462e+00 * time: 6.200401067733765 102 1.888384e+03 1.707199e+00 * time: 6.226569890975952 103 1.888381e+03 6.198984e-01 * time: 6.252886056900024 104 1.888380e+03 5.171082e-01 * time: 6.288728952407837 105 1.888378e+03 1.037321e-01 * time: 6.3151938915252686 106 1.888378e+03 8.473253e-02 * time: 6.3506550788879395 107 1.888378e+03 8.364965e-02 * time: 6.376274108886719 108 1.888378e+03 8.080442e-02 * time: 6.402374029159546 109 1.888378e+03 7.873900e-02 * time: 6.437762975692749 110 1.888378e+03 7.798398e-02 * time: 6.463335990905762 111 1.888378e+03 7.788170e-02 * time: 6.488385915756226 112 1.888378e+03 7.776461e-02 * time: 6.5234410762786865 113 1.888378e+03 9.023586e-02 * time: 6.548877954483032 114 1.888378e+03 1.631370e-01 * time: 6.584585905075073 115 1.888378e+03 2.768691e-01 * time: 6.610511064529419 116 1.888377e+03 4.462313e-01 * time: 6.636148929595947 117 1.888377e+03 6.643167e-01 * time: 6.671735048294067 118 1.888375e+03 8.433175e-01 * time: 6.697432994842529 119 1.888374e+03 7.596473e-01 * time: 6.7236809730529785 120 1.888373e+03 3.637851e-01 * time: 6.760334014892578 121 1.888372e+03 8.305224e-02 * time: 6.786334991455078 122 1.888372e+03 2.084516e-02 * time: 6.821507930755615 123 1.888372e+03 2.056416e-02 * time: 6.846122980117798 124 1.888372e+03 2.044079e-02 * time: 6.869066953659058 125 1.888372e+03 2.035197e-02 * time: 6.900161027908325 126 1.888372e+03 2.021266e-02 * time: 6.92298698425293 127 1.888372e+03 1.998168e-02 * time: 6.945894956588745 128 1.888372e+03 3.162094e-02 * time: 6.9776930809021 129 1.888372e+03 5.510007e-02 * time: 7.001025915145874 130 1.888372e+03 9.277177e-02 * time: 7.024463891983032 131 1.888372e+03 1.528967e-01 * time: 7.057027101516724 132 1.888372e+03 2.462112e-01 * time: 7.080802917480469 133 1.888372e+03 3.799880e-01 * time: 7.113508939743042 134 1.888371e+03 5.312357e-01 * time: 7.137594938278198 135 1.888369e+03 6.019766e-01 * time: 7.1617701053619385 136 1.888367e+03 4.665348e-01 * time: 7.194713115692139 137 1.888366e+03 1.404917e-01 * time: 7.218880891799927 138 1.888365e+03 8.513280e-02 * time: 7.24288010597229 139 1.888364e+03 1.244285e-01 * time: 7.275374889373779 140 1.888364e+03 1.028231e-01 * time: 7.298995018005371 141 1.888364e+03 5.163326e-02 * time: 7.331707954406738 142 1.888364e+03 5.148616e-02 * time: 7.3558509349823 143 1.888364e+03 3.147247e-02 * time: 7.3795740604400635 144 1.888364e+03 2.104597e-02 * time: 7.412302017211914 145 1.888364e+03 6.541596e-03 * time: 7.435370922088623 146 1.888364e+03 2.538502e-03 * time: 7.460169076919556 147 1.888364e+03 4.361857e-03 * time: 7.491796970367432 148 1.888364e+03 3.034845e-03 * time: 7.514419078826904 149 1.888364e+03 5.961460e-04 * time: 7.545598030090332
FittedPumasModel
Dynamical system type: Closed form
Number of subjects: 30
Observation records: Active Missing
DV: 540 0
Total: 540 0
Number of parameters: Constant Optimized
0 13
Likelihood approximation: FOCE
Likelihood optimizer: BFGS
Termination Reason: GradientNorm
Log-likelihood value: -1888.3638
-----------------------
Estimate
-----------------------
tvvc 3.976
tvq 0.04239
tvvp 3.7249
tvcl_hep_M 1.7174e-7
tvcl_hep_F 0.13348
tvcl_ren_M 0.19378
tvcl_ren_F 0.042211
Ω₁,₁ 0.14046
Ω₂,₂ 0.081349
σ_add 0.032171
σ_prop 0.061007
dCRCL_M 0.94821
dCRCL_F 1.9405
-----------------------As before, our loglikelihood is higher (implying lower objective function value). This is expected since we also added six new parameters to the model.
5 Step 4 - Model Comparison
Now that we’ve fitted all of our models we need to compare them and choose one for our final model.
We begin by analyzing the model metrics. This can be done with the metrics_table function:
metrics_table(fit_base_model)WARNING: using deprecated binding Distributions.MatrixReshaped in Pumas.
, use Distributions.ReshapedDistribution{2, S, D} where D<:Distributions.Distribution{Distributions.ArrayLikeVariate{1}, S} where S<:Distributions.ValueSupport instead.17×2 DataFrame
| Row | Metric | Value |
|---|---|---|
| String | Any | |
| 1 | Successful | true |
| 2 | Estimation Time | 3.353 |
| 3 | Subjects | 30 |
| 4 | Fixed Parameters | 0 |
| 5 | Optimized Parameters | 8 |
| 6 | DV Active Observations | 540 |
| 7 | DV Missing Observations | 0 |
| 8 | Total Active Observations | 540 |
| 9 | Total Missing Observations | 0 |
| 10 | Likelihood Approximation | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} |
| 11 | LogLikelihood (LL) | -1901.82 |
| 12 | -2LL | 3803.63 |
| 13 | AIC | 3819.63 |
| 14 | BIC | 3853.96 |
| 15 | (η-shrinkage) η₁ | -0.015 |
| 16 | (η-shrinkage) η₂ | -0.013 |
| 17 | (ϵ-shrinkage) DV | 0.056 |
metrics_table(fit_covariate_model_wt)17×2 DataFrame
| Row | Metric | Value |
|---|---|---|
| String | Any | |
| 1 | Successful | true |
| 2 | Estimation Time | 1.992 |
| 3 | Subjects | 30 |
| 4 | Fixed Parameters | 0 |
| 5 | Optimized Parameters | 8 |
| 6 | DV Active Observations | 540 |
| 7 | DV Missing Observations | 0 |
| 8 | Total Active Observations | 540 |
| 9 | Total Missing Observations | 0 |
| 10 | Likelihood Approximation | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} |
| 11 | LogLikelihood (LL) | -1896.46 |
| 12 | -2LL | 3792.93 |
| 13 | AIC | 3808.93 |
| 14 | BIC | 3843.26 |
| 15 | (η-shrinkage) η₁ | -0.014 |
| 16 | (η-shrinkage) η₂ | -0.012 |
| 17 | (ϵ-shrinkage) DV | 0.056 |
metrics_table(fit_covariate_model_wt_crcl)17×2 DataFrame
| Row | Metric | Value |
|---|---|---|
| String | Any | |
| 1 | Successful | true |
| 2 | Estimation Time | 3.632 |
| 3 | Subjects | 30 |
| 4 | Fixed Parameters | 0 |
| 5 | Optimized Parameters | 10 |
| 6 | DV Active Observations | 540 |
| 7 | DV Missing Observations | 0 |
| 8 | Total Active Observations | 540 |
| 9 | Total Missing Observations | 0 |
| 10 | Likelihood Approximation | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} |
| 11 | LogLikelihood (LL) | -1892.41 |
| 12 | -2LL | 3784.82 |
| 13 | AIC | 3804.82 |
| 14 | BIC | 3847.73 |
| 15 | (η-shrinkage) η₁ | -0.014 |
| 16 | (η-shrinkage) η₂ | -0.012 |
| 17 | (ϵ-shrinkage) DV | 0.056 |
metrics_table(fit_covariate_model_wt_crcl_sex)17×2 DataFrame
| Row | Metric | Value |
|---|---|---|
| String | Any | |
| 1 | Successful | true |
| 2 | Estimation Time | 7.546 |
| 3 | Subjects | 30 |
| 4 | Fixed Parameters | 0 |
| 5 | Optimized Parameters | 13 |
| 6 | DV Active Observations | 540 |
| 7 | DV Missing Observations | 0 |
| 8 | Total Active Observations | 540 |
| 9 | Total Missing Observations | 0 |
| 10 | Likelihood Approximation | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} |
| 11 | LogLikelihood (LL) | -1888.36 |
| 12 | -2LL | 3776.73 |
| 13 | AIC | 3802.73 |
| 14 | BIC | 3858.52 |
| 15 | (η-shrinkage) η₁ | -0.013 |
| 16 | (η-shrinkage) η₂ | -0.012 |
| 17 | (ϵ-shrinkage) DV | 0.056 |
metrics_table outputs all of the model metrics we might be interested with respect to a certain model. That includes metadata such as estimation time, number of subjects, how many parameters were optimized and fixed, and number of observations. It also includes common model metrics like AIC, BIC, objective function value with constant (-2 loglikelihood), and so on.
We can also do an innerjoin (check our Data Wrangling Tutorials) to get all metrics into a single DataFrame:
all_metrics = innerjoin(
metrics_table(fit_base_model),
metrics_table(fit_covariate_model_wt),
metrics_table(fit_covariate_model_wt_crcl),
metrics_table(fit_covariate_model_wt_crcl_sex);
on = :Metric,
makeunique = true,
);
rename!(
all_metrics,
:Value => :Base_Model,
:Value_1 => :Covariate_Model_WT,
:Value_2 => :Covariate_Model_WT_CRCL,
:Value_3 => :Covariate_Model_WT_CRCL_SEX,
)17×5 DataFrame
| Row | Metric | Base_Model | Covariate_Model_WT | Covariate_Model_WT_CRCL | Covariate_Model_WT_CRCL_SEX |
|---|---|---|---|---|---|
| String | Any | Any | Any | Any | |
| 1 | Successful | true | true | true | true |
| 2 | Estimation Time | 3.353 | 1.992 | 3.632 | 7.546 |
| 3 | Subjects | 30 | 30 | 30 | 30 |
| 4 | Fixed Parameters | 0 | 0 | 0 | 0 |
| 5 | Optimized Parameters | 8 | 8 | 10 | 13 |
| 6 | DV Active Observations | 540 | 540 | 540 | 540 |
| 7 | DV Missing Observations | 0 | 0 | 0 | 0 |
| 8 | Total Active Observations | 540 | 540 | 540 | 540 |
| 9 | Total Missing Observations | 0 | 0 | 0 | 0 |
| 10 | Likelihood Approximation | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} | Pumas.FOCE{Optim.NewtonTrustRegion{Float64}, Optim.Options{Float64, Nothing}} |
| 11 | LogLikelihood (LL) | -1901.82 | -1896.46 | -1892.41 | -1888.36 |
| 12 | -2LL | 3803.63 | 3792.93 | 3784.82 | 3776.73 |
| 13 | AIC | 3819.63 | 3808.93 | 3804.82 | 3802.73 |
| 14 | BIC | 3853.96 | 3843.26 | 3847.73 | 3858.52 |
| 15 | (η-shrinkage) η₁ | -0.015 | -0.014 | -0.014 | -0.013 |
| 16 | (η-shrinkage) η₂ | -0.013 | -0.012 | -0.012 | -0.012 |
| 17 | (ϵ-shrinkage) DV | 0.056 | 0.056 | 0.056 | 0.056 |
We can also use specific functions to retrieve those. For example, in order to get a model’s AIC you can use the aic function:
aic(fit_base_model)3819.6299849528186aic(fit_covariate_model_wt)3808.9264607805967aic(fit_covariate_model_wt_crcl)3804.8179473717055aic(fit_covariate_model_wt_crcl_sex)3802.7275243740673We should favor lower values of AIC, hence, the covariate model with weight, creatinine clerance, and different sex effects on clearance should be preferred, i.e. covariate_model_wt_crcl_sex.
5.1 Goodness of Fit Plots
Additionally, we should inspect the goodness of fit of the model. This is done with the plotting function goodness_of_fit, which should be given a result from a inspect function. So, let’s first call inspect on our covariate_model_wt_crcl_sex candidate for best model:
inspect_covariate_model_wt_crcl_sex = inspect(fit_covariate_model_wt_crcl_sex)[ Info: Calculating predictions. [ Info: Calculating weighted residuals. [ Info: Calculating empirical bayes. [ Info: Evaluating dose control parameters. [ Info: Evaluating individual parameters. [ Info: Done.
FittedPumasModelInspection
Likelihood approximation used for weighted residuals: FOCEAnd now we pass inspect_covariate_model_wt_crcl_sex to the goodness_of_fit plotting function:
goodness_of_fit(inspect_covariate_model_wt_crcl_sex)
The idea is that the population predictions (preds) capture the general tendency of the observations while the individual predictions (ipreds) should coincide much more closely with the observations. That is exactly what we are observing in the top row subplots in our goodness of fit plot.
Regarding the bottom row, on the left we have the weighted population residuals (wres) against time, and on the right we have the weighted individual residuals (iwres) against ipreds. Here we should not see any perceived pattern, which indicates that the error model in the model has a mean 0 and constant variance. Like before, this seems to be what we are observing in our goodness of fit plot.
Hence, our covariate model with allometric scaling and different sex creatinine clearance effectw on clearance is a good candidate for our final model.
6 Time-Varying Covariates
Pumas can handle time-varying covariates. This happens automatically if, when parsing a dataset, read_pumas detects that covariate values change over time.
6.1 painord Dataset
Here’s an example with an ordinal regression using the painord dataset from PharmaDatasets.jl. :painord is our observations measuring the perceived pain in a scale from 0 to 3, which we need to have the range shifted by 1 (1 to 4). Additionally, we’ll use the concentration in plasma, :conc as a covariate. Of course, :conc varies with time, thus, it is a time-varying covariate:
painord = dataset("pumas/pain_remed")
first(painord, 5)5×8 DataFrame
| Row | id | arm | dose | time | conc | painord | dv | remed |
|---|---|---|---|---|---|---|---|---|
| Int64 | Int64 | Int64 | Float64 | Float64 | Int64 | Int64 | Int64 | |
| 1 | 1 | 2 | 20 | 0.0 | 0.0 | 3 | 0 | 0 |
| 2 | 1 | 2 | 20 | 0.5 | 1.15578 | 1 | 1 | 0 |
| 3 | 1 | 2 | 20 | 1.0 | 1.37211 | 0 | 1 | 0 |
| 4 | 1 | 2 | 20 | 1.5 | 1.30058 | 0 | 1 | 0 |
| 5 | 1 | 2 | 20 | 2.0 | 1.19195 | 1 | 1 | 0 |
@rtransform! painord :painord = :painord + 1;
describe(painord, :mean, :std, :first, :last, :eltype)8×6 DataFrame
| Row | variable | mean | std | first | last | eltype |
|---|---|---|---|---|---|---|
| Symbol | Float64 | Float64 | Real | Real | DataType | |
| 1 | id | 80.5 | 46.1992 | 1 | 160 | Int64 |
| 2 | arm | 1.5 | 1.11833 | 2 | 0 | Int64 |
| 3 | dose | 26.25 | 31.9017 | 20 | 0 | Int64 |
| 4 | time | 3.375 | 2.5183 | 0.0 | 8.0 | Float64 |
| 5 | conc | 0.93018 | 1.49902 | 0.0 | 0.0 | Float64 |
| 6 | painord | 2.50208 | 0.863839 | 4 | 4 | Int64 |
| 7 | dv | 0.508333 | 0.500061 | 0 | 0 | Int64 |
| 8 | remed | 0.059375 | 0.236387 | 0 | 0 | Int64 |
unique(painord.dose)4-element Vector{Int64}:
20
80
0
5As we can see we have 160 subjects were given either 0, 5, 20, or 80 units of a certain painkiller drug.
:conc is the drug concentration in plasma and :painord is the perceived pain in a scale from 1 to 4.
First, we’ll parse the painord dataset into a Population. Note that we’ll be using event_data=false since we do not have any dosing rows:
pop_ord =
read_pumas(painord; observations = [:painord], covariates = [:conc], event_data = false)
Note
We won’t be going into the details of the ordinal regression model in this tutorial. We highly encourage you to take a look at the Ordinal Regression Pumas Tutorial for an in-depth explanation.
We’ll build an ordinal regression model declaring :conc as a covariate. In the @derived block we’ll state the the likelihood of :painord follows a Categorical distribution:
ordinal_model = @model begin
@param begin
b₁ ∈ RealDomain(; init = 0)
b₂ ∈ RealDomain(; init = 1)
b₃ ∈ RealDomain(; init = 1)
slope ∈ RealDomain(; init = 0)
end
@covariates conc # time-varying
@pre begin
effect = slope * conc
# Logit of cumulative probabilities
lge₁ = b₁ + effect
lge₂ = lge₁ - b₂
lge₃ = lge₂ - b₃
# Probabilities of >=1 and >=2 and >=3
pge₁ = logistic(lge₁)
pge₂ = logistic(lge₂)
pge₃ = logistic(lge₃)
# Probabilities of Y=1,2,3,4
p₁ = 1.0 - pge₁
p₂ = pge₁ - pge₂
p₃ = pge₂ - pge₃
p₄ = pge₃
end
@derived begin
painord ~ @. Categorical(p₁, p₂, p₃, p₄)
end
endPumasModel
Parameters: b₁, b₂, b₃, slope
Random effects:
Covariates: conc
Dynamical system variables:
Dynamical system type: No dynamical model
Derived: painord
Observed: painordFinally we’ll fit our model using NaivePooled estimation method since it does not have any random-effects, i.e. no @random block:
ordinal_fit = fit(ordinal_model, pop_ord, init_params(ordinal_model), NaivePooled())[ Info: Checking the initial parameter values. [ Info: The initial negative log likelihood and its gradient are finite. Check passed. Iter Function value Gradient norm 0 3.103008e+03 7.031210e+02 * time: 2.002716064453125e-5 1 2.994747e+03 1.083462e+03 * time: 0.533405065536499 2 2.406265e+03 1.884408e+02 * time: 0.5377020835876465 3 2.344175e+03 7.741610e+01 * time: 0.5419151782989502 4 2.323153e+03 2.907642e+01 * time: 0.5461940765380859 5 2.318222e+03 2.273295e+01 * time: 0.5503830909729004 6 2.316833e+03 1.390527e+01 * time: 0.5543379783630371 7 2.316425e+03 4.490883e+00 * time: 0.5582060813903809 8 2.316362e+03 9.374519e-01 * time: 0.5620231628417969 9 2.316356e+03 1.928785e-01 * time: 0.5658309459686279 10 2.316355e+03 3.119615e-02 * time: 0.5696070194244385 11 2.316355e+03 6.215513e-03 * time: 0.5733990669250488 12 2.316355e+03 8.313206e-04 * time: 0.5773200988769531
FittedPumasModel
Dynamical system type: No dynamical model
Number of subjects: 160
Observation records: Active Missing
painord: 1920 0
Total: 1920 0
Number of parameters: Constant Optimized
0 4
Likelihood approximation: NaivePooled
Likelihood optimizer: BFGS
Termination Reason: GradientNorm
Log-likelihood value: -2316.3554
-----------------
Estimate
-----------------
b₁ 2.5112
b₂ 2.1951
b₃ 1.9643
slope -0.38871
-----------------As expected, the ordinal model fit estimates a negative effect of :conc on :painord measured by the slope parameter.
7 Missing Data in Covariates
The way how Pumas handles missing values inside covariates depends if the covariate is constant or time-varying. For both cases Pumas will interpolate the available values to fill in the missing values. If, for any subject, all of the covariate’s values are missing, Pumas will throw an error while parsing the data with read_pumas.
For both missing constant and time-varying covariates, Pumas, by default, does piece-wise constant interpolation with “next observation carried backward” (NOCB, NONMEM default). Of course for constant covariates the interpolated values over the missing values will be constant values. This can be adjusted with the covariates_direction keyword argument of read_pumas. The default value :right is NOCB and :left is “last observation carried forward” (LOCF, Monolix default).
Hence, for LOCF, you can use the following:
pop = read_pumas(pkdata; covariates_direction = :left)along with any other required keyword arguments for column mapping.
Note
The same behavior for covariates_direction applies to time-varying covariates during the interpolation in the ODE solver. They will also be piece-wise constant interpolated following either NOCB or LOCF depending on the covariates_direction value.
8 Categorical Covariates
In some situations, you’ll find yourself with categorical covariates with multiple levels, instead of binary or continuous covariates. Categorical covariates are covariates that can take on a finite number of distinct values.
Pumas can easily address categorical covariates. In the @pre block you can use a nested if ... elseif ... else statement to handle the different categories.
For example:
@pre begin
CL = if RACE == 1
tvcl * (WT / 70)^dwtdcl * exp(η[1]) * drace1dcl
elseif RACE == 2
tvcl * (WT / 70)^dwtdcl * exp(η[1]) * drace2dcl
elseif RACE == 3
tvcl * (WT / 70)^dwtdcl * exp(η[1]) * drace3dcl
end
endHere we are conditioning the clearance (CL) on the RACE covariate by modulating which population-level parameter will be used for the clearance calculation: drace1dcl, drace2dcl, and drace3dcl.
There’s nothing wrong with the code above, but it can be a bit cumbersome to write and read. In order to make it more readable and maintainable, you can use the following example:
@pre begin
raceoncl = race1cl^(race == 1) * race2cl^(race == 2) * race3cl^(race == 3)
CL = tvcl * raceoncl
endHere we are using the ^ operator to raise each race value to the power of the race1cl, race2cl, and race3cl values. If any of the race values is not equal to the race value, the result will be 1, otherwise it will be the respective race1cl, race2cl, or race3cl value.
9 Conclusion
This tutorial shows how to build covariate model in Pumas in a workflow approach. The main purpose was to inform how to:
- parse covariate data into a
Population - add covariate information into a model
We also went over what are the differences between constant and time-varying covariates and how does Pumas deal with missing data inside covariates.