Lecture 4 & 5: Respiratory & Circulatory Physiology

Question 1

What is respiration?

Answer 1

• Cellular respiration: oxidation of food (e.g. glucose) to generate ATP. Energy production via aerobic metabolism. (End goal of getting O2 in body, but not gonna cover)
• External respiration: gas exchange , O2 from external environment (air/H2O), lungs, through circulatory system, to cells.

Question 2

External respiration

Answer 2

Functions:
1. O2 uptake & CO2 excretion
2. pH regulation

Types of gas movement:
- exchange via diffusion: 1. between respiratory surfaces, alveoli in lungs, O2 diffusing from lungs into bloodstream. 2.from blood into cell.
- bulk transport: 1.movement of external media = ventilation, breathing air into lungs or movement of H2O (fish) across respiratory surface (gills). 2. During circulation, transport of O2 & CO2 in circularly fluid.

Question 3

How fast does diffusion occur?

Answer 3

Fick’s Law of Diffusion:
- adaptations that speed up diffusion
- e.g. alveoli cells in lungs (unit of gas exchange), airflow entering the lungs/alveoli, rich in O2, O2 diffusing into capillary which circles the alveoli & CO2 being removed. This happening by diffusion.
- R = rate of diffusion, D = diffusion constant (equal to R) (specific for each molecule, for O2 it ^ if dissolved in H2O, which is why gas exchange surfaces are moist), A = area over which diffusion occurs, ΔP = pressure difference between 2 sides (^concentration gradient^rate of diffusion), d = distance over which diffusion occurs (thickness of membrane).

Question 4

Adaptive respiratory physiology

Answer 4

1. Insect: spiracles & tracheal system (directly deliver O2 to respiring tissues)
2. Bird: air sacs (maintain direction of flow)
3. Fish: respiratory exchange across gill

Aim of all gas exchange surfaces is to improve rate of gas exchange

Question 5

Gas exchange surfaces

Answer 5

Characteristics of gas exchange surfaces: permeable to gases, moist (dissolved O2 ^rate), thin & maximise SA

Question 6

Gas exchange surfaces: CUTANEOUS RESPIRATION (skin breathers)

Answer 6

• O2 diffuse across skin.
• e.g. flatworm, small, aquatic, few cells thick.
• e.g. earthworm, need to stay moist (or suffocates) so excrete mucus & bury themselves in damp soils, but larger so has circulatory system, skin is 1 cell thick, gases diffuse across & diffuse into dense network of capillaries & into circulatory system.
• e.g. reptiles, scales impair O2 transport across skin, but do still undergo skin breathing

Question 7

Gas exchange surfaces

Answer 7

Water-breathers: external evaginated gills, in fish & crustaceans they protected, fish has bony flap that covers gills, crustaceans have carapace, gills can be big & complex as supported by H2O.

Air-breathers: invaginated lungs or tracheae, need to keep respiratory gas organs moist so internal or invaginated, need advanced structural system for gas exchange organs.

Question 8

Water & skin breathing

Answer 8

• over 200 species of amphibian fish can breathe by H2O & air.
• e.g. mangrove killifish
• huge plasticity in this organ
• gene expression and structural changes in skin to do with remodelling of the skin in order to skin breath, reduces thickness of skin, more permeable to H2O & dissolved O2, over a few days will cause reduction in amount of collagen in skin so more permeable to O2 .

Question 9

Water and air breathing

Answer 9

• tadpoles are aquatic but adult frogs spend lots of time breathing air.
• in tadpoles gills & skin are important in uptaking O2, as moves through metamorphosis & becomes adult gills diminish, lungs develop but skin also important in uptaking O2. BUT different when comes to CO2 excretion, excrete most CO2 by skin.

Question 10

How is gas exchanged achieved?

Answer 10

1. Simple diffusion (e.g. flatworm), skin breather
2. Convection of external medium only: cnidarians(e.g. jellyfish, corals) & sponges, which use flagella/tentacles to circulate surrounding H2O in order to absorb O2 (&nutrients)(no circulatory system), sponge has series of osculum pores which moves tentacles to draw H2O across body surface & out through pore, that movement if the H2O is allowing diffusion of O2 into tissues.
3. Convection of internal medium only: e.g. earthworm = skin breather & circulatory system, is convecting O2 within body (in circulatory system)
4. Convection of internal & external media: animals that ventilate (move external medium, air/H2O) also have circulatory media which will circulate O2 in bloodstream.

Question 11

Challenges for Water breathers

Answer 11

• High viscosity & density: H2O is 850x more viscous than air, high viscosity of H2O slows down diffusion of gases through gills (& requires more energy), fish evolved specialized respiratory structures, e.g. gills with thin & delicate filaments. The large surface area & thin structure facilitate efficient gas exchange despite high viscosity of H2O.
• Low O2 solubility: a) limited amount of dissolved O2 impact respiratory efficiency, BUT large SA of gills, Countercurrent Exchange Mechanisms, O2-deprived blood moves through gill filaments, it exposed to oxygenated H2O, O2 diffuses from H2O into blood,CO2 diffuses from blood into the H2O, maximises O2 uptake.
• Low diffusion rate:

Question 12

Diversity in aquatic invertebrates

Answer 12

1. Gills: Crustaceans (e.g., Crabs, Shrimp, Lobsters): gills located in branchial chambers or appendages, & H2O is circulated over gill surfaces to facilitate gas exchange. Mollusks (e.g., Clams, Mussels): gills extract O2 from H20, use cilia to bring H2O over the gills.

Question 13

Fish gills

Answer 13

A) Active Bicarbonate Pump: CO2 converted to carbonic acid (H2CO3) in blood, H2CO3 dissociates into bicarbonate ions (HCO3-)& hydrogen ions (H+), on basolateral membrane (the side facing the blood) of gill epithelial cells, HCO3- pump actively transports HCO3- out of gill epithelial cells into blood, to maintain electrochemical balance, chloride ions (Cl-) move into gill epithelial cells, compensating for export of HCO3-, on the apical membrane (the side facing the gill’s external environment), HCO3- are transported across membrane & released into surrounding H2O.
B) Ram ventilation: in some fish, use forward movement through H2O to maintain continuous flow of oxygenated H2O over their gills.

Question 14

Fish gills

Answer 14

Structure:
1. Operculum: protective bony flap, shields & supports gill, pair on each side of head, helps control H2O flow over gills.
2. Gill Arches: support gill filaments, in pairs on each side of head.
3. Gill Filaments: thin projections, extend from gill arches, primary sites for gas exchange between blood & surrounding H2O, covered in respiratory epithelium, contain network of capillaries.
4. Gill Lamellae:Gill filaments subdivided into smaller structures= gill lamellae,^ SA for gas exchange, covered in thin layer of epithelial cells, close proximity of H2O& blood in lamellae allows for efficient diffusion of gases.

Question 15

Fish gills

Answer 15

Countercurrent flow maximises gas exchange

• maximizes gas exchange efficiency
• lamellae ^ SA for gas exchange.
• flow of H2O over the gill filaments & flow of blood within the filaments occur in opposite directions.
• ensures O2 concentration in H2O remains ^ than O2 concentration in blood & CO2 concentration in blood is ^ than in H2O, facilitating efficient removal.

Question 16

Water vs air breathing

Answer 16

Watch lecture: 40:40

Question 17

Transition from water to land

Answer 17

Evolutionary pushes & pulls:

Push Factors:
1. Competition for Resources: move to land offered new niches & opportunities to exploit untapped resources, reducing competition.
2. Predation Pressure: escape predation or exploit new strategies for avoiding predators.
3. Limited Oxygen Availability: O2 diffusion (& dissolving of O2) in H2O less efficient than in air, terrestrial environments provide a ^ concentration of O2.
4. Temperature Regulation: Land offers wider range of temp fluctuations.
5. Access to Sunlight: plants access sunlight more efficiently.

Pull Factors:
1. Access to New Food Sources: e.g. terrestrial plants, insects, and other organisms.
2. Reduced Competition: terrestrial habitats initially had fewer organisms adapted to land, reducing competition for resources.
3. Invasion of New Habitats: expanding their ecological range.
4. Evolution of Locomotion on Land: development of limbs.

Key Respiratory Adaptations:
1. Lung Evolution: evolved from simple sac-like structures to complex organs in diff terrestrial vertebrates.
2. Cutaneous Respiration: breathe through skin.
3. Tracheal Systems: Insects evolved, a network of tubes, deliver air directly to tissues.
4. Amphibian Adaptations: e.g. frogs and salamanders, developed cutaneous respiration & pulmonary respiration to meet O2 needs during diff life stages.
5. Amniotic Egg: in reptiles allowed to reproduce on land, specialized membranes that facilitate gas exchange.
6. Avian Respiratory System: Birds, with air sacs, allowing for continuous flow of air through lungs.

Question 18

Air breathers

Answer 18

Advantage: ^ O2 availability

Challenges:
- water loss
- heat loss
- structural support

Question 19

Insects

Answer 19

(Air breathing invertebrates)

• chitin rings reinforce trachea
• O2 enters via spiracles

Question 20

Vertebrates

Answer 20

How complexity of lungs have ^ through starting at:
1. In amphibians (salamander) to (frog)
2. Reptile (lizard)
3. Mammal (human)

Question 21

Mammals

Answer 21

Maximising SA for gas exchange:

Supported by cartilage

Alveoli

Lungs occupy most of chest cavity

Question 22

Mammals

Answer 22

Minimising diffusion distance

• thin membrane
• counter current exchange not possible

Question 23

Birds

Answer 23

Air capillaries minimise diffusion distance, blood capillaries maximise blood flow

Question 24

Birds

Answer 24

Flow through air movement enhances gas exchange

Question 25

Birds

Answer 25

Cross-current exchange is more efficient for oxygen extraction