YR2-CH5&6-LSN3
HAVE READY:
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KERBOODLE PAGE 67-71
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Slide 1: Slide
BiologieMiddelbare schoolhavo, vwoLeerjaar 2
This lesson contains 20 slides, with interactive quiz, text slides and 1 video.
Items in this lesson
HAVE READY:
GOOGLE CLASSROOM
KERBOODLE PAGE 67-71
Slide 1 - Slide
TODAY:
- instruction on theory for today
- work on in class assignments.
Slide 2 - Slide
Lesson 3: Gass exchange
- I understand what gas exchange is and which gasses need to be exchanged;
- I have a basic understanding of diffusion and how diffusion drives gas exchange;
- I can explain how are organs adapted for optimal gas exchange
- I can explain the differences between organs for gas exchange in different animals.
Slide 3 - Slide
Slide 4 - Video
GAS EXCHANGE
- To move O2 from the (inhaled) air to the blood
- To move CO2 from the blood to the (exhaled) air
HOW does gas exchange happen?
Slide 5 - Slide
Diffusion
Slide 6 - Slide
Explain how diffusion drives gas exchange in the alveoli in the lungs
Slide 7 - Open question
Diffusion in the alveoli
diffusion
displacement of small molecules
from high concentration
to low concentration (with the concentration gradient)
Why does O2 go into the blood?
Why does CO2 go into the air?
DISPLACEMENT from high to low
Slide 8 - Slide
But there is more to it...
Remember the membrane?
for diffusion to occur the membrane must be passable, therefore thin! There needs to be a short diffusion distance.
Slide 9 - Slide
But there is more to it...
You need a lot of O2!
In order to get enough oxygen to your cells, you need a lot of alveoli
There is a high surface area for gas exchange
Slide 10 - Slide
So diffusion is optimized by...
- Large concentration gradient (high oxygen in the alveoli by ventilating, low oxygen in the blood by transporting it away).
- Small diffusion distance (very thin wall between the alveolus and capillary)
- Large surface area (a lot of alveoli present)
Slide 11 - Slide
But then it goes wrong.
Animals become short of breath when there is not enough uptake of oxygen in the blood
Diffusion is NOT optimal
On the next slide, a pulmonary disease is briefly described.
Slide 12 - Slide
Asthma (example I-question)
Asthma is a common condition in children, with the most common symptom of being regularly short of breath. The muscles around their bronchioles constrict, making the airway narrower, impairing the gas exchange in the alveoli. As a result, less oxygen is diffusing into the blood, causing the shortness of breath
Discuss in your table group:
- Which of the criteria for optimal diffusion is negatively impacted here? Choose between: concentration gradient, diffusion distance or surface area.
- Explain as a result of this oxygen uptake is therefore lower.
- Write your definitive group answer in your note book
timer
7:00
Slide 13 - Slide
Less ventilation in case of asthma
muscle tissue in bronchiole walls contract >
airways become narrower>
less ventilation >
less O2 in alveoli
the O2 concentration gradient is diminished!
Slide 14 - Slide
Gas exchange in other animals
Put google to good use: Find information on gas exchange in the following animals:
- fish (gills)
- insects (tracheae / spiracles)
- amphibians
- worms
- unicellular organisms (amoeba)
Describe in no more than 4 sentences:
- Describe the differences in organs between these animals and lungs of mammals
- Describe how diffusion is optimized in those animals
timer
15:00
Slide 15 - Slide
FISH use gills
- use mouth to press water past gills
- arches filled with filaments
- filaments lined with lamella
- counter current: water flow is AGAINST the blood flow for optimal diffusion
Slide 16 - Slide
WORMS use their skin
AMFIBIANS use skin AND lungs
- skin is very thin and covered with mucus
- oxygen from air dissolves in mucus
- oxygen then passes through skin
- oxygen can only travel short distances
Slide 17 - Slide
Insects use tracheae
- = spiracles
- air tubes through entire body
- completely separated from blood flow
- blood does not carry oxygen (that is why it is not red)
Slide 18 - Slide
AMOEBA is unicellular
- so small it doesn't require any adaptations for gas exchange
- O2 and CO2 simply pass through the cell membrane
Slide 19 - Slide
WHAT TO DO NOW:
- work on HW for lesson 3
- work on HW for lesson 4
Have them both completed next week
