Physiology 1, 2 and 3 - Intro, membrane, membrane transport Flashcards Preview

1st Year - Principles > Physiology 1, 2 and 3 - Intro, membrane, membrane transport > Flashcards

Flashcards in Physiology 1, 2 and 3 - Intro, membrane, membrane transport Deck (58)
Loading flashcards...
1
Q

Tissue?

A

Group of cells with similar structure and specialise function

2
Q

Organs?

A

2 or more types of primary tissues that function together to perform a particular function(s)

3
Q

Body systems?

A

groups of organs that perform related functions and work together to achieve a common goal(s)

4
Q

Homeostasis

A

Stable internal environment (maintenance of steady states within our bodies by co-ordinated physiological mechanisms)

5
Q

In order to maintain homeostasis, what just a control system do?

A

Sense deviations from normalIntegrate this info. with other relevant info.Make appropriate adjustments in order to restore a controlled variable to its desired value

6
Q

2 classes of control systems and explanation

A

Intrinsic control (local controls that are inherent in an organ)Extrinsic controls (regulatory mechanism initiated outside an organ - this is accomplished by nervous and endocrine systems)

7
Q

Feedforward?Feedback?

A

Feedforward - responses made in anticipation of a change - usually act in combination with negative feedback)Feedback - response made after a change has been detected

8
Q

Negative feedback?Positive feedback?

A

Negative - opposes initial changePositive - amplifies initial change

9
Q

Components of a negative feedback system

A

Sensor, control centre (compared sensor’s input with a set point), effectors

10
Q

Example of positive feedback

A

Uterine contractions during labour become increasingly stronger until birth of baby

11
Q

What are the major components of a cell membrane? (3)

A

Mostly lipids (phospholipids and cholesterol) and proteins (plus small amounts of carbohydrates)

12
Q

How do you describe the appearance of the plasma membrane through an electron microscope?

A

Trilaminar

13
Q

What are the 2 main parts of a phospholipid? Charged? hydrophilic or hydrophobic?

A

Head (negatively charged, polar, hydrophilic)Tail (uncharged, nonpolar, hydrophobic)

14
Q

What makes up the lipid bilayer of the cell membrane?

A

Phospholipids

15
Q

The lipid bilayer is rigid. True or false?

A

False - it is fluid

16
Q

What is the purpose of having cholesterol interspersed in the phospholipid bilayer?

A

To prevent the phospholipids sticking together (contributes to the fluidity and stability of the membrane)

17
Q

What word describes proteins embedded in the lipid e.g. receptors?

A

Integral proteins

18
Q

What word described proteins that extend through the membrane e.g. transporters, channels?

A

Transmembrane proteins

19
Q

What word describes proteins that do not penetrate the membrane (most commonly intracellular) e.g. receptor-associated enzymes?

A

Peripheral proteins

20
Q

What are short carbohydrate chains found on the membrane often bound to?What is the name for the layer formed by the membrane carbohydrates which coat the surface of the cell (“the sugar coating”)?

A

Usually membrane proteins (glycoproteins) and to a lesser extent lipids (glycolipids)Glycocalyx

21
Q

What are the 3 important functions of the lipid bilayer?

A

It forms the basic structure of the membraneIts hydrophobic interior serves as a barrierIt is responsible for the fluidity of the membrane (enables the cell to change shape)

22
Q

What type of membrane proteins are located on the inner membrane surface and interact with secretariat vesicles leading to exocytosis of the vesicle contents?

A

Docking-marker acceptors

23
Q

What is an example of a cell adhesion molecule that helps hold cells within tissue together?

A

Cadherins

24
Q

What do the short carbohydrate chains on the outer surface act as?

A

Self-identity markers that enable cells to identify and interact with one another

25
Q

Role of carbohydrate chains on cell surface in tissue growth?

A

Makes sure cells do not overgrow their own territory

26
Q

What are the 3 types of specialised cell junctions?

A

DesmosomesTight junctionsGap junctions

27
Q

What are desmosomes?

A

Adhering junctions that anchor cells together, especially in tissues subject to stretching e.g. skin

28
Q

What are tight junctions?

A

Join the lateral edges of epithelial cells near their lumens (apical) membranes (tight or leaky)

29
Q

What are gap junctions?

A

Communicating junctions that allow the movement of charge carrying ions and small molecules between 2 adjacent cells

30
Q

Is the plasma membrane permeable?

A

Selectively permeable

31
Q

What 2 properties influence whether a particles can permeate the plasma membrane without assistance?

A

Solubility of the particle in lipidSize of the particle

32
Q

What 2 driving forces can cause something to move across a membrane?

A

PassiveActive (requires ATP)

33
Q

What 2 forces drive molecules and ions that can diffuse across the membrane?

A

Diffusion down a concentration gradient, and/orMovement along an electrical gradient

34
Q

What is Fick’s law of diffusion?

A

In addition to concentration gradient, the following factors influence rate of net diffusion:The magnitude of the concentration gradientThe surface area of the membrane across which diffusion is taking placeThe lipid solubility of the substanceThe molecular weight of the substanceThe distance through which diffusion must take place

35
Q

In addition to concentration gradient, what is ion movement also affected by?

A

Electrical charge e.g. cations tend to move towards more negatively charged areas

36
Q

What is osmosis?

A

The net diffusion of water down its own concentration gradient

37
Q

Why can water molecules pass through/ permeate the plasma membrane more readily than would be expected from solubility in lipid?

A

Due to aquaporins (water channels)

38
Q

What is osmolarity?

A

the concentration of osmotically active particles present in a solution

39
Q

What are the units of osmolarity?

A

Osmoles/ litre (Osm)

40
Q

What is the approximate osmolarity of body fluids?

A

Approx. 300 mOsm

41
Q

What is tonicity?

A

The effect a solution has on cell volume

42
Q

What are the units of tonicity?

A

No units

43
Q

Isotonic?

A

Doesn’t change cell volume

44
Q

Hypotonic?

A

Increase in cell volume

45
Q

Hypertonic?

A

Decrease in cell volume

46
Q

What happens in substance mediated transport?

A

Substance binds onto a specific carrier which undergoes a conformational change which transports the substance

47
Q

What important characteristics determine the kind and amount of material transferred across the membrane?

A

Specificity - each carrier is specialised to transport a specific substance or a few closely related chemical compoundsSaturation (transport maximum, Tm)Competition

48
Q

What are the 2 forms of carrier-mediated transport?

A

Facilitated diffusion (Not requiring energy) - transfer downhillActive transport (requiring energy)- transfer uphill

49
Q

What are the 2 forms of active transport?

A

Primary active transportSecondary active transport

50
Q

What is primary active transport?

A

Energy is directly required to move a substance across its concentration gradient

51
Q

What is secondary active transport?

A

The transfer of a solute across the membrane is always coupled with the transfer of the ion that supplies the driving force (typically Na+) - energy source comes from another reaction

52
Q

Is the Na+K+ATPase involved in primary or secondary active transport?

A

Primary

53
Q

What does the Na+K+ATPase do?

A

Transports 3 X Na+ out of the cell for every 2 X K+ in

54
Q

What are the 3 important roles of the Na+K+ pump?

A

Helps establish Na+ and K+ concentration gradients across the plasma membrane of all cellsHelps regulate cell volume by controlling concentration of solutes inside the cellThe energy used to drive the pump indirectly serves as the energy source for secondary active transport

55
Q

What are the mechanisms by which secondary active transport can occur?

A

Symport (co-transport)Antiport (exchange or countertransport)

56
Q

What is symport (co-transport)?

A

The solute and Na+ move in the same direction e.g. glucose absorption at the apical membrane of enterocytes

57
Q

What is antiport?

A

The solute and Na+ move in opposite directions (Na+ into, solute out of the cell)

58
Q

Is vesicular tranport passive or active?

A

Always active as requires energy for vesicle formation and movement within the cell