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Respiratory and Respiratory and cardiovascular responses cardiovascular responses to oxygen and carbon to oxygen and carbon dioxide levels in internally dioxide levels in internally pipped chicken embryospipped chicken embryos
Stephanie Sbong, Department of Biological Sciences, College of Arts and Sciences & Honors College
Dr. Edward Dzialowski, Department of Biological Sciences, College of Arts and Sciences
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Lab GoalsLab GoalsTo understand the development
of human respiratory and cardiovascular systems using avian models◦To characterize the ductus arteriosi
in chicken embryos
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Mammalian Mammalian Ductus Ductus ArteriosusArteriosus
Fetal Circulatory System
Vessel that connects pulmonary artery with aorta
Shunts blood away from lungs to body
Closes upon birth Randell et al., 2002Circulation In Womb
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Avian Ductus Avian Ductus ArteriosiArteriosi
Notice: ◦Aorta branches left, not right.
◦Two longer ductus arteriosi
rpato lung
lpato lung
aortapa
LDARDA
rv
da
lv
to body and CAM
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Lab GoalsLab GoalsTo understand the development
of human respiratory and cardiovascular systems using avian models◦To characterize the ductus arteriosi
in chicken embryos
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FocusFocus How does O2 uptake at the CAM
and interact during internal pipping?
How does CO2 uptake at the CAM and lungs interact during internal pipping?
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Rahn, Ar, Paganelli. “How Bird Eggs Breathe” 1979
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Pre-pipped Internally Pipped
CAM CAM + Lungs
12% O2 5% CO2
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Rahn, Ar, Paganelli. “How Bird Eggs Breathe” 1979
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FocusFocus How does O2 uptake at the CAM
and interact during internal pipping?
How does CO2 uptake at the CAM and lungs interact during internal pipping?
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Lung and CAM RespirationLung and CAM Respiration
Air Cell Gas Mixture12% O2, 5% CO2, 83%
N2
EggAir
Measure lung and CAM oxygen consumption separately
Open flow respirometry
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Air cell
Respirometer
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OO22 Level of Exposure Level of Exposure
Egg O2 Air Cell O2
21% 21%21% 5%15% 12%15% 21%15% 5%30% 12%30% 21%30% 5%
Egg O2 Air Cell O2
21% 12%
CONTROL TESTING
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VO2total (ml O2 min-1)
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7
VO
2lun
g (
ml O
2 2
min
-1)
0.0
0.1
0.2
0.3
0.4
0.5
Lung metabolic rate vs. total Lung metabolic rate vs. total metabolic rate at normoxiametabolic rate at normoxia
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ResultsResultsThere was a positive correlation
between Vo2 lungs and Vo2 total.
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VO2total (ml O2 min-1)
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7
VO
2lun
g (
ml O
2 2
min
-1)
0.0
0.1
0.2
0.3
0.4
0.5
Lung metabolic rate vs. total Lung metabolic rate vs. total metabolic ratemetabolic rate
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ResultsResultsThere was a positive correlation
between Vo2 lungs and Vo2 total.
Different stages of internal pipping
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Changes in Lung MR vs. changes in CAM Changes in Lung MR vs. changes in CAM MRMR
VO2CAM (ml O2 min-1)
- 0.3 - 0.2 - 0.1 0.0 0.1 0.2 0.3
VO
2lun
g (
ml
O2
min
-1)
- 0.3
- 0.2
- 0.1
0.0
0.1
0.2
0.3egg 21% : AC 5%
egg 21% : AC 21%
egg 15% : AC 12%
egg 30% : AC 12%
egg 15% : AC 5%
egg 30% : AC 21%
egg 30% : AC 5%
egg 15% : AC 21%
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Changes in Lung MR vs. changes in CAM Changes in Lung MR vs. changes in CAM MRMR
VO2CAM (ml O2 min-1)
- 0.3 - 0.2 - 0.1 0.0 0.1 0.2 0.3
VO
2lun
g (
ml
O2
min
-1)
- 0.3
- 0.2
- 0.1
0.0
0.1
0.2
0.3egg 21% : AC 5%
egg 21% : AC 21%
egg 15% : AC 12%
egg 30% : AC 12%
egg 15% : AC 5%
egg 30% : AC 21%
egg 30% : AC 5%
egg 15% : AC 21%
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ResultsResultsEmbryos have the ability to use the CAM
or lungs to compensate for each other.
Significance:◦ CAM hyperoxic, lungs hypooxic increased
VO2total
◦ Both CAM and lungs are hypoxic both decrease
Could response be due to changes in ventilation patterns?
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AC 5% O2 AC 21% O2 AC 2.5% CO2
Tidal volume
Frequency
103 ± 6 96 ± 7 55 ± 6*
103 ± 3 105 ± 6 96 ± 7
Changes in ventilation after changing air cell O2 and CO2 Data presented as % of control
Pulmonary ventilation
107 ± 8 101 ± 9 51 ± 6 *
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VentilationVentilation
At internal pipping:◦ Ventilatory oxygen chemosensitivity has little
role in controlling O2 exchange
◦ Develops during external pipping
◦ CO2 chemosensitivity is functioning
in ventilation plays no role in controlling gas exchange in response to hypoxia or hypoeroxia
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Blood FlowBlood Flow
Dr. Dzialowski, Upward Bound Students
Microspheres Technique
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Time (min)
0 10 20 30 40 50 60
Org
an B
lood
Flo
wLu
ng B
lood
Flo
w
0.1
1
10
CAM
Brain
5% O2 into air cell
* **
Repeated Measures ANOVA CAM p = 0.013Brain p = 0.001
Hypoxia
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* * *
Repeated Measures ANOVA CAM p = 0.024Brain p = 0.26
Hyperoxia
Time (min)
0 10 20 30 40 50 60
Org
an B
lood
Flo
wLu
ng B
lood
Flo
w
0.1
1
10
CAM
Brain
21% O2 into air cell
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ResultsResultsLung hypoxia increased blood
flow through the ductus arteriosiLung hyperoxia decreased blood
flow through the ductus arteriosi
Achieved by altering blood flow to the lungs and through the ductus arteriosi and the interatrial foramina
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FocusFocus How does O2 uptake at the CAM
and interact during internal pipping?
How does CO2 uptake at the CAM and lungs interact during internal pipping?
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COCO22 Level of Exposure Level of Exposure
Egg CO2 Air Cell CO2
0% 0%0% 2.5%
0% 10%
5% 5%
Egg CO2 Air Cell CO2
0% 5%
CONTROL TESTING
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VO2CAM (ml O2 min-1)
-0.3 -0.2 -0.1 0.0 0.1 0.2 0.3
V
O2
lun
g (
ml O
2 m
in-1
)
-0.3
-0.2
-0.1
0.0
0.1
0.2
0.3egg 0% : AC 0%egg 0% : AC 2.5%egg 0% : AC 10%egg 5% : AC 5%
Changes in Lung MR vs. changes in CAM Changes in Lung MR vs. changes in CAM MRMR
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ResultsResultsLung hypercapnia no change
VO2totalLung hypocapnia decreasing
VO2totalEgg hypercapnia increase both
VO2total
Brain senses CO2 levels (carbon dioxide chemosensitivity)
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Final ConclusionsFinal ConclusionsDuring internal pipping, chicken embryos
have two sites of respiration: CAM and air cell.
When there is a change in oxygen level at one respiration site, the other site compensates.◦ Blood flow is the compensation mechanism for O2
changes.
O2 chemosensitivity in the IP chicken embryo is weak and developing, while CO2 chemosensitivity is functional.
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Future ResearchFuture ResearchMeasure ventilation and blood
flow patterns during hypercapnia and hypocapnia
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QUESTIONS?QUESTIONS?
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Acknowledgments Acknowledgments Dr. Dzialowski, Faculty MentorDr. Eve and Dr. Cox, Honors
CollegeUpward Bound Students:
◦Miguel Cavazos◦Felicia Guerrero◦Heather Morgan