Download - Remainder of the Respiratory System
Remainder of the Respiratory System...
Any problems with the homework? (Worksheets, SR questions?)
Did you copy down/describe Figure 8.20?◦ Define the following terms: tidal volume,
inspiratory reserve volume, expiratory reserve volume, vital capacity, residual volume.
◦ What is respiratory efficiency? (page 264)
From last class...
We have already touched on the idea of counter-current flow, which occurs in ___________ by their specialized ventilation structure, the __________.
While water flows from the front of the fish towards the back, the blood vessels lining the gills are arranged so that blood flows in the opposite direction (back to front).
As blood flows past the gills, the most oxygen-depleted blood (coming from body) meets the most oxygen-depleted water.
Concentration of oxygen in the blood is so low, that the concentration of oxygen in the low-oxygen water is even higher. What will happen to the oxygen? ______________
As blood moves forward, it becomes richer in oxygen, but is still not as oxygen-rich as the water. Therefore, the oxygen _____________ into the blood.
THE LEVEL OF OXYGEN IN THE BLOOD NEVER REACHES THAT OF OXYGEN IN THE WATER. THEREFORE, OXYGEN NATURALLY ________________ INTO THE BLOOD ALONG THE GILLS.
Counter-current Flow
The numbers represent the comparative amount of oxygen in the water and blood vessels.
Notice how the amount of oxygen in the water is always higher than the amount of oxygen in the blood. Therefore, oxygen will _______________ into the blood.
Which system is more efficient? Why do you think this is necessary?
Counter-Current Mammalian
Birds need a of oxygen in order to fly for long periods of time.◦ The arctic tern migrates half-way around the
world each year! Why would they need an increased amount
of oxygen in their body cells? ________________________________________________________________________________________
They have a specialized respiratory system.
Respiratory System in Birds
Birds have a series of air sacs that branch out from the two lungs.◦ Air sacs permeate most cavities of the bird – even
some bones!◦ Number of air sacs varies from species to species◦ Air sacs have tubes connecting them to the lungs.
Two kinds of air sacs:◦ Anterior: _____________ and Posterior: ___________
NO GAS EXCHANGE OCCURS IN THESE SACS.◦ Function: to ventilate the lungs in a highly
efficient manner.◦ In a mammal: arrangement means that much air
that makes contact with the respiratory surface is air left over form the last act of inspiration.
◦ In birds: true circulation of air.
Fresh air is continually moved across the lung surface, whether the bird is inhaling or exhaling.
THEREFORE, oxygenated respiratory medium in contact with the moist respiratory surface of the lungs at all times.
Additionally, the bird’s circulatory system arranged in a fashion in which counter-current exchange occurs.
Two adaptations of bird’s respiratory system: ___________________ and ____________________________________________.
SR, page 267, #1-4
Seatwork/Homework
For the most part, breathing is an unconscious act. ◦ Do you THINK about breathing when you are
sleeping, studying, resting, reading, watching TV? Breathing, along with many other body
reflexes, is controlled by a part of the brain called the MEDULLA OBLONGATA.
8.4 – Control and Regulation
we quickly lose control over our own breathing when we change environments (high altitude) or level of activity.
Since muscles need oxygen, a lack of sufficient oxygen will lead to an increased breathing rate.
Study: people seem to breath at an equal rate when in an oxygen tank or in normal air. Levels of oxygen do not affect breathing rate. How do we know this?: _____________________
____________________________________________
The Control of Breathing
Increase in CO2 in the body leads to a quicker breathing rate.
Increased physical exertion increased cellular respiration increased emission of CO2 from cells.
This CO2 enters the bloodstream and goes passed the lungs. If there is an extraneous amount of CO2 in the blood, not all CO2 will be able to be exchanged into the lungs, and will continue to the MEDULLA OBLONGATA.
The medulla oblongata sends nerve impulses to initiate faster movement of the intercostal muscles and diaphragm.
O2 levels DO play a SMALL part in breathing rate◦ Aorta (main artery at top of heart) and carotid
(brings blood to brain) contain chemoreceptors that respond to oxygen levels. When low, sends stimuli to the medulla oblongata increase breathing.
Inspiratory Volume◦ Inhaling more air than normal lungs and alveoli
stretch stretch receptors in walls of alveoli send signals medulla oblongata stop inhalation.
Other factors...
‘Thin Air’: therefore less oxygen. Hypoxia: Altitude Sickness
◦ Lack of energy, shortness of breath, headaches, nausea.
◦ Symptoms will subside after a couple weeks. temporary adaptations to meet challenge of gas
exchange at high altitudes. When first at high altitudes, body cannot
extract enough oxygen from the air to meet metabolic needs.
Breathing at High Altitudes
Respiratory◦ Increased breathing rate.
Circulatory◦ Production of more red blood cells. ________________________________________________
So what would happen to this individual with these temporary adaptations when they return to normal altitudes?
_____________________________________________
Temporary Adaptations:
Many serious athletes train in higher altitudes.
Within a few weeks, red blood cell count drops to normal.
Training in High Altitudes
Some populations have evolved at high altitudes, showing genetic adaptations.◦ More alveoli◦ More lung capillaries
http://news.nationalgeographic.com/news/2004/02/0224_040225_evolution.html
Populations in High Altitude
Read the Thinking Lab on page 269. We will have a short discussion on the questions.
Coach’s Corner
Human respiratory system can usually adjust quickly to meet physical demands.
If internal body or external environment changes too much, process of respiration will be limited.
Some causes of Respiratory Failure:1) Drowning2) Carbon Monoxide Poisoning3) Smoking4) Air Pollution
Respiratory Impairment
1) Drowning◦ Laryngospasm
Reflex closing of the larynx In up to 10% of drowning cases, it is due to own body’s
‘asphyxiation’ rather than result of water entering the lungs.
◦ Fresh water Drowning Water washes away lubricating film of alveoli alveoli
collapse and gas exchange ends.◦ Salt water Drowning
Salt water has very high concentration of _______. Fluid from capillaries will be drawn from the __________________ to the _______________. THIS fluid builds up and prevents gas exchange to occur.
Remember: the water in lakes and oceans contain oxygen gas! If the lubricating film was not washed away, or if fluid from the blood did not build up in the alveoli, gas exchange could still occur.
Carbon Monoxide Poisoning◦ Binds to oxygen receptors in red blood cells 200X more
tightly than oxygen.◦ Therefore: __________________________________.◦ Symptoms similar to those of hypoxia.◦ People with CO poisoning suffocate but can breath. Why?
___________________________________________. Smoking
◦ Cilia paralyzed◦ Contains carbon monoxide◦ Tar causes brittle lungs and lung cancer.
Air Pollution◦ Carbon monoxide, nitrogen oxides, chlorine, and methane
asthma (sudden constriction of bronchial tubules). ◦ Smog: in urban areas. Combination of pollutants, heat,
and sunlight similar affects as cigarette smoke.
We will do the investigation on page 271 together.
Investigation
Section Review, page 273◦ #1, 2, 4.
Seatwork/Homework
Transport & Circulation
Chapter 9
Your hand contains over a km of blood vessels.
No cell in your hand is more than a cell’s width away from a blood vessel.
Why is it important for human body cells to be in contact with a circulatory system?◦ Cells need to take in
____________________________________________________________________________________________________
◦ Cells need to expel__________________________________________________
Interesting Facts
Plants transport material through _________________________ tissue.◦ ____________ transports water and minerals UP
through a plant.◦ ____________ transports sugar/food DOWN through
a plant.
OTHER ORGANISMS HAVE TRANSPORT SYSTEMS!
The Task of Transporation
Amoeba: single-celled Protist. ◦ Animal-like protist: ____________________________.◦ Respiratory gases and nutrients enter/exit cell through
diffusion or active transport across the cell membrane. Cnidaria: simple, multicellular animals.
◦ Hydra and jellyfish. ◦ Fluid taken in through mouth. Requirements necessary for
cellular respiration brought from body cavity to every cell no specialized circulatory system.
Planaria: a type of flatworm.◦ High metabolic rate (energy-requiring processes)◦ Can rely on diffusion ◦ Digestive cavity all cells of body SIMPLE TRANSPORT OCCURS MOSTLY THROUGH DIFFUSION.
Simple Transport
1) On the board, write out the balanced chemical equation for cellular respiration.
2) Indicate how the respiratory system applies to this equation.
3) How do you think the Circulatory system applies to this?
Let’s Bring it back to the Basics
Most multicellular organisms cannot rely on diffusion or active transport to bring materials from the external environment to cells of the internal tissues.
Two major types of complex systems evolved:1) Open2) Closed
Specialized Transport Systems
Ex// grasshopper◦ Only one large blood vessel: aorta.◦ Aorta carries blood into the body cavity, which is
subdivided into sinuses (chambers) that bring blood/body fluids into contact with internal cells.
◦ Co-ordinated movements of the body helps move blood around inside of the insect.
◦ Blood bathes the cells directly.◦ OPEN TRANSPORT SYSTEM: a transport system in
which blood is not always contained within blood vessels.
◦ Fluid can ‘slosh’ back and forth: not great for larger organisms.
1) Open
Include annelids and vertebrates.◦ Annelids: ___________________________◦ Vertebrates: ________________________
CLOSED TRANSPORT SYSTEM: blood does not bathe cells directly, but is pumped through a network of vessels in close proximity to cells.◦ BLOOD CIRCULATES IN ONE DIRECTION!
2) Closed
Circulation in Annelids (earthworms) Circulation in Fish Circulation in Amphibians (frogs &
salamanders) Circulation in Birds and Mammals
WE WILL FOCUS ON MAMMALS FIRST.
4 Examples of Closed Transport Systems:
SR, Page 287.#1, 2, 5, 6.
Seatwork/Homework
There are three major parts of the human circulatory system:◦ Pulmonary◦ Cardiac◦ Systemic
The Mammalian Circulatory System
Brings blood from the heart to the lungs, and back to the heart.◦ Why would we want blood to go to the lungs?
_________________________◦ Why would we want that blood to go back to the
heart? ___________________
Pulmonary
Blood flow within the heart. This is where blood gets pumped to go the
rest of the body (lungs or body). Why is this blood flow necessary?:
_____________________________________
Cardiac
Blood from the heart goes to most body cells.◦ 80-90% of blood is in your systemic system.
Which parts of your body might the systemic system serve?
____________________________________________________________________________________________________________________
Systemic
What is the point of the human circulatory system?
____________________________________________ We have:
◦ A heart (pumps blood)◦ A pulmonary system (from heart to lungs to heart)◦ A systemic system (from heart to body to heart)
If given these three components, how would you organize them in order to meet the demands of the body? Why?
Overview of the Circulatory System:
Overview of the Circulatory System (II):
Away from the heart: arteries and arterioles. To the heart: veins and venules. Super small arterioles and venules: capillaries.
◦ Transport oxygen and nutrients TO body cells and carry carbon dioxide and waste FROM body cells.
Blood Vessels
Transport O2, glucose, and nutrients to the body cells.
Takes wastes and CO2 away from the body cells.
Capillaries are the tiniest of the tiniest blood vessels. They branch ‘in’ to one another to form venules.
Venules then branch in to one another to form veins.
Capillaries:
Artery arteriole capillary venule vein
Of course there are!.. If there wasn’t we would be dead/extinct.◦ Every centimetre of our body has some kind of
adaptation that we don’t even think about.
Are there adaptations to our blood vessels?
How can blood make it back to the heart (pump?)
(Note: aorta, arterioles, capillaries, and veins)
Check this out...
Arteries are built for:◦ Pressure◦ Stamina◦ They have elastic/strong walls (for waves of
blood: this is what you feel when you take your pulse).
Veins are built for:◦ Keeping blood from going ‘backwards.’◦ The blood in veins have little ‘push’◦ Therefore, veins are equipped with valves that
prevent blood from flowing backward.
Arteries vs. Veins
Arteries:◦ Larger, more elastic vessels
Veins:◦ Smaller. ◦ Valves to keep back-flow.
Adaptations of Arteries and Veins:
Artery arteriole _____________ venule vein.
REMEMBER THAT IN THIS CASE, THE BLOOD NEVER LEAVES THE CAPILLARIES. ONLY FLUIDS/GASES CAN MOVE BETWEEN CELLS AND BLOOD.
Capillaries: