Term
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Definition
| Net diffusion rate of a gas across a fluid membrane is proportional to the thickness of a membrane. |
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Term
| What does the Fick Law calculate ? |
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Definition
| Exchange rates of gases across membranes |
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Term
| Give an example of a efficient gas exchange |
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Definition
| Membrane surface area in the alveoli may be on the order of 100 square meters and have a thickness of less than a millionth of a meter ! |
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Term
| Define Unidirectional Ventilation |
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Definition
|
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Term
| What does an effective respiratory organ require ? |
|
Definition
A large surface
A thin cuticle |
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Term
| How can gas exchange be maximized ? |
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Definition
One can increase the surface area,partial pressure gradient between body and environment.
Thick ness of diffusion barrier must be minimized. |
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Term
|
Definition
Blood with higher oxygen content meets water with the highest oxygen
content so that oxygen diffuses into the blood. HIGH EFFICIENCY OF EXTRACTION ! |
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Term
| How does blood flow through the gills ? |
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Definition
Deoxygenated blood reaches the gills by way of afferent branchial arteries.
The blood passes through the gill lamellae where it is oxygenated.
It then passes to efferent branchial arteries and on to the body. |
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Term
| Efferent Definition, give an example. |
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Definition
Directed away from a central organ or section
An element vessel |
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Term
Afferent Definition, give an example
|
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Definition
Carrying inward to a central organ,
Gill Arch |
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Term
| Do water breathers have to ventilate more or less ? Why ? |
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Definition
| More. They move water over gills for gas exchange . |
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Term
| What do fish do in Ram Ventilation ? |
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Definition
Fish open their mouth while swimming foward. They alter gape to change flow over the gill.
if a fish swims forward with its mouth open, water will flow across the gills without active pumping by the muscles surrounding the buccal and opercular cavities. |
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Term
| Why is Ram Ventilation Efficient ? |
|
Definition
The fish does not need to use the muscles around its buccal and opercular cavities to move water through the gills. However the fish is swimming which the opened mouth may increase drag and increase the cost of locomotion. |
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Term
| Example of obligate air breather (organism) |
|
Definition
The Electric Eel.
Mouth lined with papillae.
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Term
| What does an effective respiratory organ require ? |
|
Definition
| A large surface area and a thin cuticle. |
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Term
|
Definition
-Unidirectional pumping of water over respiratory epithelium (tissues),
-Tissues folded into filaments and folded again in secondary lamaelle
-Countercurrent blood flow
-Filaments stacked very close together forming a mesh. |
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Term
| What are the evolutionary beginnings of lungs ? |
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Definition
| Gas flled chamber connected to alimentary canal |
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Term
| Positive pressure ventilation |
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Definition
| Pumps air into lung. Most air breathing fish, reptiles and amphibians. |
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Term
|
Definition
Few fish, some reptiles, mammals and birds.
Change volume and pressure of thoracic cavity, to draw air in , elastic recoil pushes air out.
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Term
|
Definition
|
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Term
| How do lungs extract more oxygen ? |
|
Definition
| Increase of surface area through internal folding. |
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Term
| Which animals have septae lungs ? |
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Definition
|
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Term
|
Definition
| The thoracic cavity is basically the chest, including everything between the neck and the diaphragm. It’s home to the thoracic organs and is protected by the thoracic cage. The heart and lungs are essential for survival |
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Term
| What does the parabronchi do ? |
|
Definition
| Allows unidirectional flow of air through lungs |
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Term
| Describe avian ventilation |
|
Definition
-Air flows directly into posterior sacs and dorsobronchii
-Air from posterior sacs flow into lung
-Air from lung flows into anterior sacs
-Air from anterior sacs flows to outside |
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Term
| What is air flow controlled by in avian respiration ? |
|
Definition
|
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Term
|
Definition
| Air flow is unidirectional in the lungs although ventilation is tidal |
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Term
| Gas Exchange - Ficks Law. How to optimize by selection. "A" |
|
Definition
-Increse Surfarce Area
-Air: large lung
-Water: large gill, primary secondary lamallae
- |
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Term
| Gas Exchange - Ficks Law. How to optimize by selection. "d" |
|
Definition
| Decrease diffusion distance:Thin epithelim (1 cell layer) |
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Term
| Gas Exchange - Ficks Law. How to optimize by selection. "b x delta p" |
|
Definition
Blood flow relative to air/water flow
-air to blood: High, little selective pressure
-water to blood: Low, great selective pressure to maximize
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Term
| Crosscurrent flow is____ efficient than mammalian lungs and _____efficient than fish gills |
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Definition
|
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Term
|
Definition
| Not involved in gas exchange |
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Term
|
Definition
| Not directly involved in gas exchange. |
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Term
| Key features of aspiration pump |
|
Definition
expansion of ribcage by sucking in air
-expiration is partly passive
-bi directional and moves air tidally
-feeding and ventilation decoupled
-ventilate lungs more frequently. |
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|
Term
Cells of respiratory system :
Type I |
|
Definition
-most abundant
-major part of lung epithelium
-squamous, epithelial cells with platelike structure |
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|
Term
Cells of respiratory system :
Type II |
|
Definition
-Have surface villi
-produce surfactant |
|
|
Term
Cells of respiratory system :
Type III |
|
Definition
-Mitochondria rich, with brush border
-rare cells involved in NaCl uptake from lung fluid |
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|
Term
| Water breathers are more sensitive to ... |
|
Definition
|
|
Term
| Air breathers are more sensitive to ... |
|
Definition
|
|
Term
| Inspiratory Reserve Volume Definition |
|
Definition
| Volume attained by maximal inspiratory effort |
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|
Term
| Resting Tidal Volume Definition |
|
Definition
| Volume at the end of resting inspiration |
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|
Term
| Expiratory Reserve Volume Definition |
|
Definition
| Volume at the end of resting expiration |
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Term
| Residual Volume Definition |
|
Definition
| Volume attained by maximal expiratory effort |
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Term
| Process through which components of triaglycerol are broken down to form acetyl-Coa... |
|
Definition
|
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Term
|
Definition
| allow internal conditions to change with external changes |
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Term
|
Definition
maintain internal conditions at relative constant state despite changes in external conditions
-They can live in a wide variety of habitats |
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Term
| How can Tolerance Zones change on short term changes? |
|
Definition
| By: proteins, enzymes, molecules, organs, behaviors, morpholgical traits. |
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Term
|
Definition
| results from animals chronic exposure in its native habitat to new naturally occuring environmental conditions. |
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Term
|
Definition
| similarities in adaptation to similar environments |
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Term
|
Definition
Closely related species are adapted to different environments.
-Lack of phylogenetic affinity of phenotype. |
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Term
| What does indirect calorimetry measures ? |
|
Definition
| oxygen consumed by metabolism |
|
|
Term
| Slow Oxidative muscles fibres |
|
Definition
| primarly aerobic and involved in posture and sustained activity. (red) |
|
|
Term
| Fast Glycolytic Muscle Fibres |
|
Definition
| Anaerobic, and suited to sudden intermittent contraction (white) |
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Term
| If the organism is limited by ventilation, what can they or evolution do to solve this problem ? |
|
Definition
Fish- selective pressure to improve gas exchange
ventilation- unidirectional water flow over gills.
- perfusion- opposite direction of water flow. (countercurrent,maximal extraction of O2) |
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|
Term
| A lacertid lizard had a _____lung |
|
Definition
|
|
Term
| A monitor lizard has a _______lung |
|
Definition
|
|
Term
| When does ventilation limit performance ? |
|
Definition
-during excersice
-oxygen limitation |
|
|
Term
| elasmobranchs have _____ sensitive receptors, that are located in the _______. |
|
Definition
-oxygen
-branchial cavity |
|
|
Term
| Teleost fish are ______ _______. The gill nerves respond to ______ levels. |
|
Definition
internal chemoreceptors
oxygen |
|
|
Term
| Plasma is ________ fluid. There's about _____. |
|
Definition
|
|
Term
|
Definition
| hemoglobin, and transport O2 and CO2 |
|
|
Term
| A decrease in the oxygen affinity.... |
|
Definition
| will right shift or increase P50, it can aid to O2 delivery to tissues by unloading O2 that was bound to hemoglobin |
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|
Term
| Aspiration pump minimizes what ? |
|
Definition
|
|
Term
| 2,3 BPG binds to _____ site |
|
Definition
|
|
Term
| 2,3 BPG binds ______ to deoxy form of Hb (T state) and _____to oxy form (R state) |
|
Definition
|
|
Term
| What does 2,3 BPG do to curve ? |
|
Definition
| Shifts to the right, reducing O2 binding affinity ! |
|
|
Term
| 2,3 BPG is needed mainly for what ? |
|
Definition
| inside erythrocyts (RBC's) to release O2 into the tissues of the body. |
|
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Term
|
Definition
| Ability of Hb to bind to O2 |
|
|
Term
|
Definition
Right Shift Curve
-increased blood PCO2
-Decreased pH
-Higher P50 |
|
|
Term
|
Definition
| Low PO2 at tissue promps the binding of CO2 to hemoglobin. |
|
|
Term
|
Definition
| High PCO2 in the tissue right shifts the hemoglobin O2 curve and promotes unloading of O2. |
|
|
Term
|
Definition
| HIgh PO2 at the lung/gil promotes the release of CO2 bound to Hb. |
|
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Term
| Type of circulation - OPEN |
|
Definition
Haemocoel -Open space
Haemolymph- fluid |
|
|
Term
| Type of circulation - Closed |
|
Definition
-blood flows in a continuous circuit
-rapid delivery of O2 to tissues. |
|
|
Term
|
Definition
| three chambered , two atria and one ventricle. |
|
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Term
|
Definition
| partial separation, 2 atria |
|
|
Term
|
Definition
|
|
Term
|
Definition
| partial separation, 2 atria partially separated by ventricle. reducing mixing of oxygenated and deoxygenated blood. |
|
|
Term
| what does having an undivided heart do ? |
|
Definition
| allows cardiovascular adjustments and changes in blood flow during different behavioral states/periodic breathing. |
|
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Term
|
Definition
|
|
Term
| evolution of lymphatic system |
|
Definition
-venolymphatic
-pretetrapod stage
-early tetrapod stage
-higher ectotherm stage
-avian stage
-mammalian stage |
|
|
Term
|
Definition
| -selection alters frequesncy of genes that affect fitness. |
|
|
Term
|
Definition
| - cells are exposed to changing conditions |
|
|
Term
|
Definition
| No energy cost required to oppose envirinmental variation |
|
|
Term
|
Definition
| differences between environment at one point in time |
|
|
Term
|
Definition
| differences at one point in environment over a given time scale |
|
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Term
|
Definition
| Fast fuel, provides ATP. One chemical enzymatic step. |
|
|
Term
| What does creatine phosphate do ? |
|
Definition
| reverse reaction. Allows for more ATP generation. Energy is stored, combines with ADP leads to accelerated muscle recovery and hydrogen ion buffering. |
|
|
Term
| Where and how are small molecules converted to pyruvate and acetyl-coA? |
|
Definition
| cytoplasm through glycolosis. |
|
|
Term
| Where is pyruvate transferred to after cytoplasm ? |
|
Definition
|
|
Term
| Where does the kreb cycle occur ? |
|
Definition
|
|
Term
|
Definition
| metabolic pathway in which lactate produced by anarobic glycolosis in the muscles moves to the liver and its converted into glucose, which then returns to the muscles as fuel and back to lactate. |
|
|
Term
| why does O2 consumption estimate metabolic rate ? |
|
Definition
| heat released for each fuel is virtually identical to the amount of O2 consumed despite different fuel storage capacity. |
|
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Term
|
Definition
| minimum resting rate without spontaneous activity, stress, digestion. |
|
|
Term
|
Definition
| thermoneutral zone non pregnant, minimum stress after fasting. |
|
|
Term
|
Definition
| An organism that regulates its body temperature largely by exchanging heat with its surroundings |
|
|
Term
|
Definition
| An organism that generates heat to maintain its body temperature, typically above the temperature of its surroundings |
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