Post on 11-Jun-2020
Example models for ruminant
digestion and metabolism
Heidi Rossow, PhD
UC Davis School Of Veterinary Medicine,
VMTRC Tulare, CA
Intro to Molly
Representation of milk production
Short demo using BST
Exercise
WEBSITE:
http://www.vmtrc.ucdavis.edu/laboratories/metabolic/molly.cfm
Publications:Baldwin RL, France J, Gill M. 1987. Metabolism of the lactating cow I-III.
J Dairy Research 54:77-145.
Baldwin RL. 1995. Modeling ruminant digestion and metabolism.
Chapman & Hall:London.
Johnson HA, Maas JA, Calvert CC, Baldwin RL. 2008. Use of computer
simulation to Teach systems approach to Nutrition and Metabolism.
JAS 86:483-499
Neal & Thornley 1983 J Ag Sci Cambridge 101:389-400
OBJECTIVE
Bridge gap between basic knowledge
of cow digestion and metabolism,
and animal performance
Nutrients
Milk
Nutrients
Digestion
Absorption
Metabolism
Reproduction Genetics
Environment
Management
Health
State Variables
Animal Element
Amino acids
(Lys His Met/Cys Other)
Glucose
Acetate
Fatty Acids
Adipose TG
Body Protein
Visceral Protein
Uenz
Milk lactose
Milk Protein
Milk Fat
Milk
Digestive ElementLarge Particles
Small Particles
Microbes
Rumen VFAs
DMI
Soluble Ash
Cellulose
Hemicellulose
Soluble, Insoluble Protein
Soluble Carbohydrates
Alpha, Beta Hexoses
Total Absorbed
Amino Acids (TAbsAa)
Absorbed
Propionic Acid (AbsPr)
Absorbed
Glucose (AbsGl)
Absorbed
Acetate (AbsAc)
Absorbed
Fatty Acids (AbsFa)Butyrate
(AbsBu)
ABSORBED NUTRIENTS
Oxidation
(BuCd)
O2
CO2
Plasma Total Amino Acids (TAa)
Made up of His, SAa, Lys, Other Aa (Aa)
Body Protein
(Pb)Visceral Protein
(Pv)
Ammonia (Am)
Urea
MILK
Protein (Pm) Lactose (Lm) Triacylglyceride (Tm)
Saliva
Pregnancy
(PRG)
Plasma Glucose
(Gl)
Oxidation
(PrCd)
O2
CO2
UreaTAaDEG TAaGlV
PrGlV
Absorbed
Lactate (AbsRLa)
Lactate in Body
(LaGlB)
Lactate in Adipose
(LaGlF)
LaGlV
LaGlV
O2
CO2
O2
CO2
Lactate in Gut
(GGlLa)
GlLmV
Storage Triglyceride (Ts)
Triose Phosphate (TpF), NADPH2 (HyF),
Fatty Acids (TsF)
Viscera
Triose Phosphate (TpV)
NADPH2 (HyV)
Oxidation
(GlCd)
O2
CO2
TAaPm, TAaLAV
Plasma Acetate
(Ac)
Oxidation
(AcCd)
O2
CO2
Glycerol
(Gy)
GlHyV GlTpV
GyGlV
TAaSal
TAaPbB
TPbAaB
TAaPvV
TPvAaV
TAaPRG
TAaAcTAaDEG
AcTsFGlTpF GlHyF
GlLaB
Plasma Fatty Acids
(Fa)
TsFaF
AcTmV FaTmV
Oxidation
(FaCd)
O2
CO2
Urea
O2
CO2
NADPH2
CO2
NADPH2
FaTsF
TpTmV
UpGl
Equations
dFa/dt = absFa + TsFaF1
-FaTsf – FaTmV – FaCd
Units = Mol/d
Integrate dFa/dt = Mol Fa
cFa = Fa / Blood volume
= Mol/L
dAc/dt = absAc + TAaAc
-AcTsF – AcTmV - AcCd
0
0.5
1
1.5
2
2.5
3
0 0.005 0.01 0.015 0.02
[S]
U (
mo
l/d
) Baseline
V
k
Example: U = Vm / (1 + Km/[S])
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
0 0.002 0.004 0.006 0.008 0.01
[S]
Ac
Tm
V
[Ac]
[Gl]
AcTmV = VAcTmV
*uenz*Kminh*INS
/(1.0+kAcTmV
/[Ac] + k1AcTm
/[Gl])
AV Difference (Mammary)
Miller et al., 1991
AV Difference (Mammary)
Miller et al., 1991
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
0 0.002 0.004 0.006 0.008 0.01
[S]
Ac
Tm
V
[Ac]
[Gl]
AcTmV = VAcTmV
*uenz*Kminh*INS
/(1.0+kAcTmV
/[Ac] + k1AcTm
/[Gl])
Representation of milk production
0
2000
4000
6000
8000
10000
12000
14000
16000
18000
0 500 1000 1500 2000 2500 3000
UCELLS
To
tal M
ilk 3
08 d
ays (
kg
)
DDMIN=15
DDMIN=19
DDMIN=23
DDMIN=27
Molly Milk Production vs. DMI
Potential milk = UCELLS
Molly milk production assumptions
1. Lactose is 4.8% of milk yield
2. Lactose production is dependent on
a-lactalbumin production
3. Relative proportion of milk fat from de
novo (Ac) and body, diet (Fa) are 50/50
4. Milk protein yield is determined by
limiting amino acid theory.
duenz = usyn - udeg
usyn = Vusyn*UCELLS*Lhor*BST/
(kusyn+Lhor*BST)
udeg = uenz*(Kudeg + KudegM*
((umave/Kmdeg)10
/(1+umave/Kmdeg)10
))
= retained milk effects
Lhor is integrated
Neal & Thornley 1983 J Ag Sci Cambridge 101:389-400
Representation of milk production
duenz = usyn - udeg
Milk Components
1. GlLmV = VGlLmf
*(VAaLA
*uenz*kminh/
(1+((kAaLA
/[Aa])EXP
))/fLAAa
2. FaTmV = VFaTmV
*uenz*INS*kminh/
(1+kFaTmV
/[Fa]+k1FaTm
/[Gl])
3. AcTmV = VAcTmV
*uenz*INS*kminh/
(1+kAcTmV
/[Ac]+k1AcTm
/[Gl])
4. AaPmV1 = VAaPm
*uenz*kminh/
(1+(kAaPm
/[Aa])EXP
)/fPmAa
GlLmV = VGlLmf
*(VAaLA
*uenz*kminh/
(1+((kAaLA
/[Aa])EXP
))/fLAAa
0
0.001
0.002
0.003
0.004
0.005
0.006
0 0.002 0.004 0.006 0.008 0.01
cAa
GlL
m
FaTmV = VFaTmV
*uenz*INS*kminh/
(1+kFaTmV
/[Fa]+k1FaTm
/[Gl])
0
1
2
3
4
5
6
0 0.002 0.004 0.006 0.008 0.01
[S]
FaT
mV
[Fa]
[Gl]
[Fa], Uenz
[Gl], Uenz
AcTmV = VAcTmV
*uenz*INS*kminh/
(1+kAcTmV
/[Ac]+kAcTm
/[Gl])
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
0 0.002 0.004 0.006 0.008 0.01
[S]
Ac
Tm
V
[Ac]
[Gl]
AaPmV1 = VAaPm
*uenz*kminh/
(1+(kAaPm
/[Aa])EXP
)/fPmAa
Demo using BST
1. Control
Go until day 308
Diet1
BST 1.0
Save data….
Model load
Model reset to T=0
Model run
2. BST lactation
Go until day 70
Diet1
BST 1.0
Save data….
Model reset to T=0
Model run
Demo using BST
3. Give BST
Go until day 308
Diet1
BST 3.0
Save data….
Model Continue
View Plot
Dmilk
Dmlktm
dmlkpm
Demo using BST
Results
Modeling ExerciseAdjust ucells to match the cow’s milk production
Total milk = 10042, total fat=355, total protein=293
iBW = 550, fBW=612, tot DMI=6197
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
0
10
20
30
40
50
60
0 50 100 150 200 250
kgkg
DIM
DMILK
DDMin
DMlkTm
DMlkPm
Modeling Exercise
Screen clipping taken: 6/17/2017 6:54 PM
Modeling Exercise - Solution
Modeling Exercise - Solution
Thanks…
http://www.vmtrc.ucdavis.edu/laboratories/metabolic/molly.cfm