Dynamic Energy Budget Theory - I Tânia Sousa with contributions from :Bas Kooijman.
Dynamic Energy Budget Theory - I
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Transcript of Dynamic Energy Budget Theory - I
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Dynamic Energy Budget Theory - I
Tânia Sousa with contributions from : Bas Kooijman
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Metabolism in a DEB
individual. Rectangles are state
variables Arrows are flows of food
JXA, reserve JEA, JEC, JEM, JET , JEG, JER, JEJ or structure JVG.
Circles are processes The full square is a fixed
allocation rule (the kappa rule)
The full circles are the priority maintenance rule.
A DEB organism Assimilation, dissipation and growth
MV - Structure
Feeding
MH - Maturity
XAJ EAJ
Assimilation
ME - ReserveMobilisation
ECJ
Offspring MER
Somatic Maintenance
Growth
Maturity Maintenance
Reproduction
Maturation
ESJ
EGJEJJ
ERJ
VGJ
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Assimilation: X(substrate)+M E(reserve) +
M + P linked to surface area
Dissipation: E(reserve) +M M
somatic maintenance: linked to surface area & structural volume
maturity maintenance: linked to maturity maturation or reproduction overheads
Growth: E(reserve)+M V(structure) + M Compounds:
Organic compounds: V, E, X and P Mineral compounds: CO2, H2O, O2 and Nwaste
3 types of aggregated chemical transformations
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Identify in these equations yXE, yPE and yEV.
Constraints on the yield coeficients Degrees of freedom
Exercises
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Identify in these equations yXE, yPE and yEV.
Constraints on the yield coeficients Degrees of freedom
Obtain the aggregated chemical reactions for
assimilation, dissipation and growth considering
that the chemical compositions are:
food CH1.8O0.5N0.2, reserve CH2O0.5N0.15,
faeces CH1.8O0.5N0.15, structure CH1.8O0.5N0.15 and
NH3.
Exercises
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Identify in these equations yXE, yPE and yEV.
Constraints on the yield coeficients Degrees of freedom
Obtain the aggregated chemical reactions for
assimilation, dissipation and growth considering
that the chemical compositions are: food
CH1.8O0.5N0.2, reserve CH2O0.5N0.15, faeces
CH1.8O0.5N0.15, structure CH1.8O0.5N0.15 and NH3.
How would you obtain the aggregate chemical
transformation?
Exercises
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What is the relationship between these
equations and , , ,, ,
and .
Considering for the juvenile
Exercises
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What is the relationship between these
equations and , , ,, ,
and .
Compute the total consumption of O2.
Write it as a function of , and .
Exercises
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What is the relationship between these
equations and , , , , , and .
Compute the total consumption of O2.
Write it as a function of , and .
Exercises
The stoichiometry of the aggregate chemical transformation that describes the organism has 3 degrees of freedom: any flow produced or consumed in the organism is a weighted average of any three other flows
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Write the energy balance for each chemical
reactor (assimilation, dissipation and growth)
Exercises
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Write the energy balance for each chemical
reactor (assimilation, dissipation and growth)
Compute the total metabolic heat production
as a function of , and .
Exercises
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Write the energy balance for each chemical
reactor (assimilation, dissipation and growth)
Compute the total metabolic heat production
as a function of , and .
If the organism temperature is constant then the
metabolic heat must be equal to the heat released
Exercises
Indirect calorimetry (estimating heat production without measuring it): Dissipating heat is weighted sum of three mass flows: CO2, O2 and nitrogeneous waste (Lavoisier in the XVIII century).
T EA T A EG T G ED T Dp J p J p J p
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Dissipating heat
Steam from a heap of moist Prunus serotina litter illustrates metabolic heat production by fungi
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Obtain an expression for the dynamics of the
reserve density mE using the equations for the dynamics of ME and MV and the following equations:
Exercises
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Obtain an expression for the dynamics of the
reserve density mE
Set dmE/dt=0 (weak homeostasis). What is the maximum value of mE?
Exercises
EAmEE
V
f x Jdm vm
dt L v M
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Obtain an expression for the dynamics of the
reserve density mE
Set dmE/dt=0 (weak homeostasis). What is the maximum value of mE?
Can you understand the meaning? What is the value for mE in weak homeostasis?
Exercises
- maximum reserve density
EAmEE
V
f x Jdm vm
dt L v M
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Obtain an expression for the dynamics of the
reserve density mE
Set dmE/dt=0 (weak homeostasis). What is the maximum value of mE?
Can you understand the meaning? What is the value for mE in weak homeostasis?
Exercises
- maximum reserve density
EAmEE
V
f x Jdm vm
dt L v M
E Emm f x m
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Obtain an expression for the dynamics of the
reserve density mE
Set dmE/dt=0 (weak homeostasis). What is the maximum value of mE?
Can you understand the meaning? Rewrite using mEm.
Exercises
- maximum reserve density
EAmEE
V
f x Jdm vm
dt L v M
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Obtain an expression for the dynamics of the
reserve density mE
Set dmE/dt=0 (weak homeostasis). What is the maximum value of mE?
Can you understand the meaning? Rewrite using mEm. What is the meaning of ?
Exercises
- maximum reserve density
E EAm
T
Em Em
m JL L
m J
EAmEE
V
f x Jdm vm
dt L v M
EAm
Em
J
J
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Obtain an expression for the dynamics of the
reserve density mE
Set dmE/dt=0 (weak homeostasis). What is the maximum value of mE?
Can you understand the meaning? Rewrite using mEm. What is the meaning of ?
Exercises
- maximum reserve density
E EAm
T
Em Em
m JL L
m J
EAmEE
V
f x Jdm vm
dt L v M
- maximum length- maximum reserve density