drmodels: Built-in dose-response models in DoseFinding
In DoseFinding: Planning and Analyzing Dose Finding Experiments
drmodels R Documentation
Built-in dose-response models in DoseFinding
Description
Dose-response model functions and gradients.
Below are the definitions of the model functions:
Emax model
f(d,\theta)=E_0+E_{max}\frac{d}{ED_{50}+d}
Sigmoid Emax Model
f(d,\theta)=E_0+E_{max}\frac{d^h}{ED^h_{50}+d^h}
Exponential Model
f(d,\theta)=E_0+E_1(\exp(d/\delta)-1)
Beta model
f(d,\theta)=E_0+E_{max}B(\delta_1,\delta_2)(d/scal)^{\delta_1}(1-d/scal)^{\delta_2}
here
B(\delta_1,\delta_2)=(\delta_1+\delta_2)^{\delta_1+\delta_2}/(\delta_1^{\delta_1}
\delta_2^{\delta_2})
and scal is a fixed dose scaling parameter.
Linear Model
f(d,\theta)=E_0+\delta d
Linear in log Model
f(d,\theta)=E_0+\delta \log(d + off)
here off is a fixed offset parameter.
Logistic Model
f(d, \theta) = E_0 + E_{\max}/\left\{1 + \exp\left[ \left(ED_{50} - d
\right)/\delta \right] \right\}
Quadratic Model
f(d,\theta)=E_0+\beta_1d+\beta_2d^2
The
standardized model equation for the quadratic model is d+\delta
d^2, with \delta=\beta_2/\beta_1.
Linear Interpolation model
The linInt model provides linear
interpolation at the values defined by the nodes vector. In virtually all
situations the nodes vector is equal to the doses used in the analysis. For
example the Mods and the fitMod function
automatically use the doses that are used in the context of the function
call as nodes. The guesstimates specified in the Mods function
need to be the treatment effects at the active doses standardized to the
interval [0,1] (see the examples in the Mods function).
Usage
emax(dose, e0, eMax, ed50)
emaxGrad(dose, eMax, ed50, ...)
sigEmax(dose, e0, eMax, ed50, h)
sigEmaxGrad(dose, eMax, ed50, h, ...)
exponential(dose, e0, e1, delta)
exponentialGrad(dose, e1, delta, ...)
quadratic(dose, e0, b1, b2)
quadraticGrad(dose, ...)
betaMod(dose, e0, eMax, delta1, delta2, scal)
betaModGrad(dose, eMax, delta1, delta2, scal, ...)
linear(dose, e0, delta)
linearGrad(dose, ...)
linlog(dose, e0, delta, off = 1)
linlogGrad(dose, off, ...)
logistic(dose, e0, eMax, ed50, delta)
logisticGrad(dose, eMax, ed50, delta, ...)
linInt(dose, resp, nodes)
linIntGrad(dose, resp, nodes, ...)
Arguments
dose
Dose variable
e0
For most models placebo effect. For logistic model left-asymptote
parameter, corresponding to a basal effect level (not the placebo effect)
eMax
Beta Model: Maximum effect within dose-range
Emax, sigmoid
Emax, logistic Model: Asymptotic maximum effect
ed50
Dose giving half of the asymptotic maximum effect
...
Just included for convenience in the gradient functions, so that
for example quadratic(dose, e0=0, b1=1, b2=3) will not throw an error
(although the gradient of the quadratic model is independent of e0, b1 and
b2).
h
Hill parameter, determining the steepness of the model at the ED50
e1
Slope parameter for exponential model
delta
Exponential model: Parameter, controlling the convexity of the
model.
Linear and linlog model: Slope parameter
Logistic model:
Parameter controlling determining the steepness of the curve
b1
first parameter of quadratic model
b2
second parameter of quadratic model (controls, whether model is
convex or concave)
delta1
delta1 parameter for beta model
delta2
delta2 parameter for beta model
scal
Scale parameter (treated as a fixed value, not estimated)
off
Offset value to avoid problems with dose=0 (treated as a fixed
value, not estimated)
resp
Response values at the nodes for the linInt model
nodes
Interpolation nodes for the linear interpolation for the linInt
model (treated as a fixed value, not estimated)
Details
The Emax model is used to represent monotone, concave dose-response
shapes. To distinguish it from the more general sigmoid emax model it is
sometimes also called hyperbolic emax model.
The sigmoid Emax model is an extension of the (hyperbolic) Emax model
by introducing an additional parameter h, that determines the steepness of
the curve at the ed50 value. The sigmoid Emax model describes monotonic,
sigmoid dose-response relationships. In the toxicology literature this model
is also called four-parameter log-logistic (4pLL) model.
The quadratic model is intended to capture a possible non-monotonic
dose-response relationship.
The exponential model is intended to capture a possible sub-linear or
a convex dose-response relationship.
The beta model is intended to capture non-monotone dose-response
relationships and is more flexible than the quadratic model. The kernel of
the beta model function consists of the kernel of the density function of a
beta distribution on the interval [0,scal]. The parameter scal is not
estimated but needs to be set to a value larger than the maximum dose. It
can be set in most functions (‘fitMod’, ‘Mods’) via the
‘addArgs’ argument, when omitted a value of ‘1.2*(maximum dose)’
is used as default, where the maximum dose is inferred from other input to
the respective function.
The linear in log-dose model is intended to capture concave shapes.
The parameter off is not estimated in the code but set to a
pre-specified value. It can be set in most functions (‘fitMod’,
‘Mods’) via the ‘addArgs’ argument, when omitted a value of
‘0.01*(maximum dose)’ is used as default, where the maximum dose is
inferred from other input to the respective function.
The logistic model is intended to capture general monotone, sigmoid
dose-response relationships. The logistic model and the sigmoid Emax model
are closely related: The sigmoid Emax model is a logistic model in
log(dose).
The linInt model provids linear interpolation of the means at the
doses. This can be used as a "nonparametric" estimate of the dose-response
curve, but is probably most interesting for specifying a "nonparametric"
truth during planning and assess how well parametric models work under a
nonparametric truth. For the function ‘Mods’ and ‘fitMod’ the
interpolation ‘nodes’ are selected equal to the dose-levels specified.
Value
Response value for model functions or matrix containing the gradient
evaluations.
References
MacDougall, J. (2006). Analysis of dose-response studies - Emax
model,in N. Ting (ed.), Dose Finding in Drug Development,
Springer, New York, pp. 127–145
Pinheiro, J. C., Bretz, F. and Branson, M. (2006). Analysis of dose-response
studies - modeling approaches, in N. Ting (ed.). Dose Finding
in Drug Development, Springer, New York, pp. 146–171
See Also
fitMod
Examples
## some quadratic example shapes
quadModList <- Mods(quadratic = c(-0.5, -0.75, -0.85, -1), doses = c(0,1))
plotMods(quadModList)
## some emax example shapes
emaxModList <- Mods(emax = c(0.02,0.1,0.5,1), doses = c(0,1))
plotMods(emaxModList)
## example for gradient
emaxGrad(dose = (0:4)/4, eMax = 1, ed50 = 0.5)
## some sigmoid emax example shapes
sigEmaxModList <- Mods(sigEmax = rbind(c(0.05,1), c(0.15,3), c(0.4,8),
c(0.7,8)), doses = c(0,1))
plotMods(sigEmaxModList)
sigEmaxGrad(dose = (0:4)/4, eMax = 1, ed50 = 0.5, h = 8)
## some exponential example shapes
expoModList <- Mods(exponential = c(0.1,0.25,0.5,2), doses=c(0,1))
plotMods(expoModList)
exponentialGrad(dose = (0:4)/4, e1 = 1, delta = 2)
## some beta model example shapes
betaModList <- Mods(betaMod = rbind(c(1,1), c(1.5,0.75), c(0.8,2.5),
c(0.4,0.9)), doses=c(0,1), addArgs=list(scal = 1.2))
plotMods(betaModList)
betaModGrad(dose = (0:4)/4, eMax = 1, delta1 = 1, delta2 = 1, scal = 5)
## some logistic model example shapes
logistModList <- Mods(logistic = rbind(c(0.5,0.05), c(0.5,0.15),
c(0.2,0.05), c(0.2,0.15)), doses=c(0,1))
plotMods(logistModList)
logisticGrad(dose = (0:4)/4, eMax = 1, ed50 = 0.5, delta = 0.05)
## some linInt shapes
genModList <- Mods(linInt = rbind(c(0.5,1,1),
c(0,1,1), c(0,0,1)), doses=c(0,0.5,1,1.5))
plotMods(genModList)
linIntGrad(dose = (0:4)/4, resp=c(0,0.5,1,1,1), nodes=(0:4)/4)
DoseFinding documentation built on Sept. 11, 2024, 9:04 p.m.
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| drmodels | R Documentation |
Built-in dose-response models in DoseFinding
Description
Dose-response model functions and gradients.
Below are the definitions of the model functions:
Emax model
f(d,\theta)=E_0+E_{max}\frac{d}{ED_{50}+d}
Sigmoid Emax Model
f(d,\theta)=E_0+E_{max}\frac{d^h}{ED^h_{50}+d^h}
Exponential Model
f(d,\theta)=E_0+E_1(\exp(d/\delta)-1)
Beta model
f(d,\theta)=E_0+E_{max}B(\delta_1,\delta_2)(d/scal)^{\delta_1}(1-d/scal)^{\delta_2}
here
B(\delta_1,\delta_2)=(\delta_1+\delta_2)^{\delta_1+\delta_2}/(\delta_1^{\delta_1}
\delta_2^{\delta_2})
and scal is a fixed dose scaling parameter.
Linear Model
f(d,\theta)=E_0+\delta d
Linear in log Model
f(d,\theta)=E_0+\delta \log(d + off)
here off is a fixed offset parameter.
Logistic Model
f(d, \theta) = E_0 + E_{\max}/\left\{1 + \exp\left[ \left(ED_{50} - d
\right)/\delta \right] \right\}
Quadratic Model
f(d,\theta)=E_0+\beta_1d+\beta_2d^2
The
standardized model equation for the quadratic model is d+\delta
d^2, with \delta=\beta_2/\beta_1.
Linear Interpolation model
The linInt model provides linear
interpolation at the values defined by the nodes vector. In virtually all
situations the nodes vector is equal to the doses used in the analysis. For
example the Mods and the fitMod function
automatically use the doses that are used in the context of the function
call as nodes. The guesstimates specified in the Mods function
need to be the treatment effects at the active doses standardized to the
interval [0,1] (see the examples in the Mods function).
Usage
emax(dose, e0, eMax, ed50)
emaxGrad(dose, eMax, ed50, ...)
sigEmax(dose, e0, eMax, ed50, h)
sigEmaxGrad(dose, eMax, ed50, h, ...)
exponential(dose, e0, e1, delta)
exponentialGrad(dose, e1, delta, ...)
quadratic(dose, e0, b1, b2)
quadraticGrad(dose, ...)
betaMod(dose, e0, eMax, delta1, delta2, scal)
betaModGrad(dose, eMax, delta1, delta2, scal, ...)
linear(dose, e0, delta)
linearGrad(dose, ...)
linlog(dose, e0, delta, off = 1)
linlogGrad(dose, off, ...)
logistic(dose, e0, eMax, ed50, delta)
logisticGrad(dose, eMax, ed50, delta, ...)
linInt(dose, resp, nodes)
linIntGrad(dose, resp, nodes, ...)
Arguments
dose |
Dose variable |
e0 |
For most models placebo effect. For logistic model left-asymptote parameter, corresponding to a basal effect level (not the placebo effect) |
eMax |
Beta Model: Maximum effect within dose-range |
ed50 |
Dose giving half of the asymptotic maximum effect |
... |
Just included for convenience in the gradient functions, so that
for example |
h |
Hill parameter, determining the steepness of the model at the ED50 |
e1 |
Slope parameter for exponential model |
delta |
Exponential model: Parameter, controlling the convexity of the
model. |
b1 |
first parameter of quadratic model |
b2 |
second parameter of quadratic model (controls, whether model is convex or concave) |
delta1 |
delta1 parameter for beta model |
delta2 |
delta2 parameter for beta model |
scal |
Scale parameter (treated as a fixed value, not estimated) |
off |
Offset value to avoid problems with dose=0 (treated as a fixed value, not estimated) |
resp |
Response values at the nodes for the linInt model |
nodes |
Interpolation nodes for the linear interpolation for the linInt model (treated as a fixed value, not estimated) |
Details
The Emax model is used to represent monotone, concave dose-response shapes. To distinguish it from the more general sigmoid emax model it is sometimes also called hyperbolic emax model.
The sigmoid Emax model is an extension of the (hyperbolic) Emax model by introducing an additional parameter h, that determines the steepness of the curve at the ed50 value. The sigmoid Emax model describes monotonic, sigmoid dose-response relationships. In the toxicology literature this model is also called four-parameter log-logistic (4pLL) model.
The quadratic model is intended to capture a possible non-monotonic dose-response relationship.
The exponential model is intended to capture a possible sub-linear or a convex dose-response relationship.
The beta model is intended to capture non-monotone dose-response relationships and is more flexible than the quadratic model. The kernel of the beta model function consists of the kernel of the density function of a beta distribution on the interval [0,scal]. The parameter scal is not estimated but needs to be set to a value larger than the maximum dose. It can be set in most functions (‘fitMod’, ‘Mods’) via the ‘addArgs’ argument, when omitted a value of ‘1.2*(maximum dose)’ is used as default, where the maximum dose is inferred from other input to the respective function.
The linear in log-dose model is intended to capture concave shapes.
The parameter off is not estimated in the code but set to a
pre-specified value. It can be set in most functions (‘fitMod’,
‘Mods’) via the ‘addArgs’ argument, when omitted a value of
‘0.01*(maximum dose)’ is used as default, where the maximum dose is
inferred from other input to the respective function.
The logistic model is intended to capture general monotone, sigmoid dose-response relationships. The logistic model and the sigmoid Emax model are closely related: The sigmoid Emax model is a logistic model in log(dose).
The linInt model provids linear interpolation of the means at the doses. This can be used as a "nonparametric" estimate of the dose-response curve, but is probably most interesting for specifying a "nonparametric" truth during planning and assess how well parametric models work under a nonparametric truth. For the function ‘Mods’ and ‘fitMod’ the interpolation ‘nodes’ are selected equal to the dose-levels specified.
Value
Response value for model functions or matrix containing the gradient evaluations.
References
MacDougall, J. (2006). Analysis of dose-response studies - Emax model,in N. Ting (ed.), Dose Finding in Drug Development, Springer, New York, pp. 127–145
Pinheiro, J. C., Bretz, F. and Branson, M. (2006). Analysis of dose-response studies - modeling approaches, in N. Ting (ed.). Dose Finding in Drug Development, Springer, New York, pp. 146–171
See Also
fitMod
Examples
## some quadratic example shapes
quadModList <- Mods(quadratic = c(-0.5, -0.75, -0.85, -1), doses = c(0,1))
plotMods(quadModList)
## some emax example shapes
emaxModList <- Mods(emax = c(0.02,0.1,0.5,1), doses = c(0,1))
plotMods(emaxModList)
## example for gradient
emaxGrad(dose = (0:4)/4, eMax = 1, ed50 = 0.5)
## some sigmoid emax example shapes
sigEmaxModList <- Mods(sigEmax = rbind(c(0.05,1), c(0.15,3), c(0.4,8),
c(0.7,8)), doses = c(0,1))
plotMods(sigEmaxModList)
sigEmaxGrad(dose = (0:4)/4, eMax = 1, ed50 = 0.5, h = 8)
## some exponential example shapes
expoModList <- Mods(exponential = c(0.1,0.25,0.5,2), doses=c(0,1))
plotMods(expoModList)
exponentialGrad(dose = (0:4)/4, e1 = 1, delta = 2)
## some beta model example shapes
betaModList <- Mods(betaMod = rbind(c(1,1), c(1.5,0.75), c(0.8,2.5),
c(0.4,0.9)), doses=c(0,1), addArgs=list(scal = 1.2))
plotMods(betaModList)
betaModGrad(dose = (0:4)/4, eMax = 1, delta1 = 1, delta2 = 1, scal = 5)
## some logistic model example shapes
logistModList <- Mods(logistic = rbind(c(0.5,0.05), c(0.5,0.15),
c(0.2,0.05), c(0.2,0.15)), doses=c(0,1))
plotMods(logistModList)
logisticGrad(dose = (0:4)/4, eMax = 1, ed50 = 0.5, delta = 0.05)
## some linInt shapes
genModList <- Mods(linInt = rbind(c(0.5,1,1),
c(0,1,1), c(0,0,1)), doses=c(0,0.5,1,1.5))
plotMods(genModList)
linIntGrad(dose = (0:4)/4, resp=c(0,0.5,1,1,1), nodes=(0:4)/4)
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