Physiology Principles Outcomes

Question 1

Define tissue.

Answer 1

A group of cells with similar structure and specialized function.

Question 2

Define organ.

Answer 2

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

Question 3

Define what is meant by “body system”.

Answer 3

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

Question 4

What is required for normal human bodily functions?

Answer 4

A stable internal environment, i.e. highly regulated optimum physiological conditions.

Question 5

Define homeostasis.

Answer 5

The maintenance of body systems within certain parameters by coordinated physiological mechanisms.

Question 6

Why is homeostasis essential for survival?

Answer 6

Certain components of the bodies internal environment MUST be maintained within narrow ranges, e.g. temperature.

Question 7

Define the three types of physiological control systems: Feedforward control, negative feedback control, positive feedback control.

Answer 7

Feedforward: responses made in anticipation of a change.

Feedback: responses made after a change has been detected.

Negative feedback: opposes the initial change.

Positive feedback: amplifies an initial change, e.g. uterine contractions.

Question 8

What is the main type of homeostatic control in the body?

Answer 8

Negative feedback.

Question 9

How does negative feedback promote stability within the body?

Answer 9

Regulates a controlled variable through a flow of information along a closed loop.

Question 10

Explain the components of a negative feedback control system.

Answer 10

Made up of:

1. A sensor. Detects changes to a controlled variable.
2. Control centre. This compares the sensor’s information with a set point.
3. Effector(s). This carries out a response to produce a desired effect.

Question 11

What might disruption of homeostasis result in?

Answer 11

Disease or death.

Question 12

List the major components of a cell plasma membrane.

Answer 12

Phospholipids forming a lipid bilayer.
Proteins.
Carbohydrates.

Question 13

Describe how the various membrane components are arranged.

Answer 13

Lipid bilayer forms the cell membrane. Membrane proteins may be integral (span/embedded/linked to lipid component of bilayer) or peripheral (adhere to cytoplasmic or extracellular surface of membrane).

Carbohydrates may attach to membrane. Or to membrane proteins, glycoproteins or glycolipids to form a layer called the glycocalyx.

Question 14

Explain how the membrane is influenced by the presence of cholesterol.

Answer 14

Cholesterol stiffens the membrane.

Question 15

Describe integral membrane proteins.

Answer 15

Integral membrane proteins may span the lipid bilayer, embed in it or link to a lipid component. They can be ligand-binding receptors, adhesion molecules, pores/channels, carriers or pumps. They may also be enzymes or participate in intracellular signaling.

Question 16

Proteins are molecules of biological specificity, and give distinctive properties on the cellular membranes in which they occur. What does this lead to amongst cell types?

Answer 16

Diversity.

Question 17

How does diffusion differ in a solution, and through a membrane?

Answer 17

In a solution, diffusion occurs from the area of high solute concentration, to the area of low solute concentration.

Diffusion through a membrane occurs only if a substance is able to permeate the membrane.

Question 18

Explain Fick’s Laws of diffusion.

Answer 18

The rate of diffusion is directly proportional to the membrane surface area and the concentration gradient.

It is inversely proportional to the membrane thickness.

Question 19

How can rates of diffusion be altered?

Answer 19

1. Magnitude of concentration gradient.
2. Surface area of the membrane.
3. Substance’s lipid solubility.
4. Molecular weight of the substance.
5. Distance through which diffusion must occur.

Question 20

Define electrochemical gradient.

Answer 20

A difference in charge between two adjacent areas, generating an electrical gradient that promotes movement of ions toward the area of opposite charge.

Question 21

Define osmosis.

Answer 21

The net diffusion of water down its own concentration gradient through a selectively permeable membrane.

Question 22

Define osmolarity.

Answer 22

Osmolarity is the concentration of osmotically active particles present in a solution.

Question 23

Define tonicity.

Answer 23

Tonicity is the effect a solution has on cell volume.

I.e. iso- (no net movement), hypo- (water moves into cells) or hyper-tonic (water moves out of cells).

Question 24

List three important characteristics of carrier mediated transport.

Answer 24

1. Specificity. Each carrier is specialized to transport a specific substance.
2. Saturation.
3. Competition. Ability to transport more than one substance.

Question 25

Define facilitated diffusion.

Answer 25

Use of a carrier to facilitate the transfer of a substance across the membrane from a high, to a low concentration.

Question 26

Define active transport.

Answer 26

Carrier is required to expend energy to transfer a substance against an existing concentration gradient.

Question 27

Define primary active transport.

Answer 27

Energy is directly required.

Question 28

Define secondary active transport.

Answer 28

Energy is required, but is not used to directly produce movement. Instead, energy in the form of an ion concentration gradient is used.

Question 29

What is the stoichiometry of the Na+ /K+ pump?

Answer 29

3 Na+ are transported out of the cell for every 2 K+ transported in.

Question 30

Name 3 important physiological roles of the Na+/K+ pump.

Answer 30

1. Helps establish Na+ and K+ concentration gradients across plasma membranes of cells.
2. Helps regulate cell volume by controlling solute concentrations inside cells.
3. Energy used to drive the pump indirectly serves as the energy source for secondary active transport.

Question 31

Name and explain two types of vesicular transport.

Answer 31

Endocytosis: “pinching off” of membrane to engulf a substance.

Exocytosis: Vesicle fused with the plasma membrane, releasing its contents into ECF.

Question 32

Describe the Baroreceptor Reflex.

Answer 32

The baroreceptor reflex detects deviations in a controlled variable, and brings about a compensatory response, resulting in the restoration of the controlled variable to its normal values.

Question 33

What is the baroreceptors role in regulating mean arterial blood pressure?

Answer 33

A deviation in mean arterial pressure is detected by a baroreceptor, which informs the control centre (medulla), instructing effectors (heart and blood vessels) to bring about a compensatory response via the process of negative feedback. This results in restoration of normal mean arterial blood pressure.

Question 34

Define blood pressure.

Answer 34

It is the outwards (hydrostatic) pressure exerted by the blood on the walls of blood vessels.

Question 35

Define systolic blood pressure. What is its normal value under resting conditions?

Answer 35

Pressure exerted by the blood on the walls of the aorta and systemic arteries when the heart contracts.

<140mmHg.

Question 36

Define diastolic blood pressure. What is its normal value under resting conditions?

Answer 36

It is the pressure exerted by the blood on the walls of the aorta and systemic arteries when the heart relaxes.

<90mmHg.

Question 37

define mean arterial blood pressure (MAP).

Answer 37

It is the average arterial blood pressure during a single cardiac cycle, which involves contraction and relaxation of the heart.

Question 38

How is mean arterial blood pressure estimated?

Answer 38

MAP= [(2x diastolic) + systolic]/3
OR
MAP= diastolic + 1/3 (systolic-diastolic)

Question 39

What is the normal range of mean arterial blood pressure?

Answer 39

70-105mmHg.

Question 40

Explain the need for regulation of mean arterial blood pressure.

Answer 40

A MAP of at least 60mmHg is needed to perfuse the coronary arteries, brain and kidneys.

Also to ensure pressure is not so high that it damages blood vessels and places strain on the heart.

Question 41

What is mean arterial blood pressure the product of?

Answer 41

Cardiac output and total peripheral resistance.

Question 42

Define cardiac output.

Answer 42

Cardiac output is the volume of blood pumped by each ventricle of the heart, per minute.

It is the product of stroke volume and heart rate.
CO= SV x HR.

Question 43

Define stroke volume.

Answer 43

The volume of blood pumped by each ventricle of the heart, per heart beat.

Question 44

Describe the role of the autonomic nervous system in control of heart rate.

Answer 44

Sympathetic division accelerates heart rate via noradrenaline acting on b1 receptors.

Parasympathetic division stimulates the vagus nerve to slow heart rate, via acetylcholine acting on muscarinic receptors.

Question 45

What causes stroke volume to increase?

Answer 45

Stroke volume is increased if the hearts contractile strength is increased.

ANS regulates stroke volume via the sympathetic division, which stimulates the ventricular myocardium.

Question 46

What are the main resistance vessels?

Answer 46

Arterioles.

Question 47

Define total peripheral resistance. Why are arterioles important to this?

Answer 47

TPR is the resistance that must be overcome for blood to flow through the circulatory system.

TPR is regulated by vascular smooth muscles. Vasoconstriction increases TPR and MAP.
Vasodilatation decreases TPR and MAP.

Question 48

Describe the principles underlying the control of total peripheral resistance by the autonomic nervous system.

Answer 48

Vascular smooth muscles are supplied by sympathetic nerve fibres (noradrenaline acting on alpha receptors).

Question 49

Arterial and arteriolar smooth muscles are mainly supplied by which type of nerves?

Answer 49

Sympathetic.

Question 50

What is vasomotor tone?

Answer 50

At rest vascular smooth muscles are partially constricted = VASOMOTOR TONE. This is caused by tonic discharge of sympathetic nerves resulting in continuous release of noradrenaline.

Question 51

What effect does increased & decreased sympathetic discharge have on TPR?

Answer 51

Increased sympathetic discharge increases vasomotor tone -> vasoconstriction, causing increased TPR and MAP, and vice versa.

Question 52

Do baroreceptors respond to sustained high blood pressure? Explain.

Answer 52

No. They respond only to acute changes. If high BP is sustained, their rate of firing decreases, and they “re-set”.

They fire again, only if there is an acute change above the new higher steady state level.

Question 53

State approximate values for the sodium, potassium and chloride ion concentrations inside and outside the cell.

Answer 53

Sodium
Intracellularly: 15mM
Extracellularly:150mM

Potassium:
Intracellularly: 150mM
Extracellularly: 5mM

Chloride:
Intracellularly: 7mM
Extracellularly: 110mM

Question 54

State the relative membrane permeabilities of sodium and potassium ions.

Answer 54

Sodium: 1
Potassium: 100 (in skeletal muscle cells)

Question 55

Define the term equilibrium potential.

Answer 55

Equilibrium potential is the membrane potential at which an ion will not diffuse through a membrane in either direction.

Question 56

State approximate values for sodium and potassium equilibrium potentials.

Answer 56

EK= -90mV.
ENa= +60mV.

Question 57

State the resting membrane potential for a typical nerve cell.

Answer 57

-70mV.

Question 58

Explain why the resting membrane potential and potassium equilibrium potential are not identical.

Answer 58

Em is membrane potential, i.e. the difference in charges across a membrane (mV).

EK is equilibrium potential, i.e. the membrane potential at which an ion will not diffuse through a membrane in either direction.

Question 59

Why is membrane potential important, particularly in excitable cells?

Answer 59

Enable flow of ions through the membrane.

Excitable cells (nerves and muscle) have the ability to produce rapid, transient changes in membrane potential when excited (action potentials).

Question 60

Why is glucose important as a metabolic fuel?

Answer 60

The brain is a glucose obligate tissue. Hypoglycaemia can lead to confusion, or a coma if untreated (“4 is the floor”).

Question 61

List 5 hormones that influence glucose production.

Answer 61

Insulin.
Glucagon.
Adrenaline (in emergencies).
Cortisol.
Growth hormone.

Question 62

Explain the changes in plasma glucose, insulin and glucagon concentrations with time after a meal.

Answer 62

After eating, plasma glucose concentration is high.

Insulin is produced to convert glucose into glycogen.

Glucagon plasma concentration is low, as it is responsible for conversion of glycogen into glucose when in the hungry state.

Question 63

What is the role of the endocrine pancreas in the control of blood glucose?

Answer 63

The endocrine pancreas contains the islets of Langerhans. They sense blood glucose levels, and secrete insulin in response.

Question 64

Describe the major physiological actions of insulin & glucagon.

Answer 64

Insulin: anabolism. Converts glucose to glycogen.

Glucagon: catabolism. Converts glycogen to glucose.

Question 65

Which tissues are insulin sensitive?

Answer 65

Liver, skeletal muscle , adipose tissue and cardiac muscle.

Question 66

Which cells are insulin sensitive?

Answer 66

brain, kidney and RBCs.

Question 67

What stimulates and what inhibits insulin release from pancreatic beta cells?

Answer 67

Feeding stimulates insulin production by beta cells.

Fasting inhibits insulin release from beta cells.

Question 68

What is Type I diabetes?

Answer 68

childhood onset, where there is little/no insulin secretion due to defective b-cell function.

Question 69

What is Type II diabetes?

Answer 69

Adult onset (until recently), insulin secretion may be normal or exceed normal, but there is an insulin sensitivity defect.

Question 70

How might diabetes be detected?

Answer 70

Glucose tolerance test.

Question 71

What stimulates and what inhibits glucagon release from pancreatic alpha cells?

Answer 71

Glucagon release from alpha cells is stimulated only in response to ingested AA proteins.

It is inhibited by glucose.

Question 72

Explain the role of adrenaline in the release of glucose in emergencies.

Answer 72

Adrenaline is released from the adrenal gland in response to stress and stimulates glycogenolysis and gluconeogenesis.

Question 73

Explain the roles of cortisol and growth hormone in providing glucose during prolonged fasting.

Answer 73

Cortisol is released from the adrenal gland in response to stress.
It stimulates gluconeogenesis.

Growth hormone is released from the anterior lobe of the pituitary gland, in response to starvation. It decreases muscle uptake of glucose and mobilises glucose from the liver.

Question 74

Explain core body temperature.

Answer 74

It is the temperature of structures deep within the body. It is homeostatically maintained, despite changes in the environment.

Question 75

Explain normothermia.

Answer 75

It is the normal core body temperature optimum for cellular metabolism and function.

Question 76

State the sites for monitoring body temperature.

Answer 76

Ear drum (tympanic), rectum, and oral cavity.

Question 77

Define the range of normal values for body temperature and the diurnal variation in body temperature

Answer 77

Differs in different individuals, roughly around 37.8oC.

Lowest in early morning.
Altered by other factors throughout the day, e.g. exercise.
Varies during menstrual cycle, higher during second half.

Question 78

Explain how the human body gains or loses heat.

Answer 78

Heat may be gained metabolically, from radiation (emission in the form of electromagnetic waves), convection (air currents) or conduction (direct contact, e.g. radiator).

Heat may be lost to the external environment through convection, conduction, radiation or evaporation.

Question 79

How does the human body maintain its core temperature at a set point?

Answer 79

homeostatic mechanisms involving a negative feedback control system.

Central thermoreceptors and peripheral thermoreceptors.

The control centre is within the hypothalamus.

The effectors are: skeletal muscle, skin arterioles and sweat glands.

Question 80

Explain how the temperature set point is raised in fever.

Answer 80

Macrophages release chemicals in response to infection/inflammation, acting as endogenous pyrogens, i.e. stimulate prostaglandin release from the hypothalamus.

This causes shivering and skin vasoconstriction, raising the body temperature to a new set point, resulting in fever.

Question 81

Distinguish the terms “fever” and “hyperthermia”.

Answer 81

Fever raises the hypothalamic temperature set point.

Hyperthermia is the extreme uncontrolled increase in body temperature, i.e. >40oC.

Question 82

Define hypothermia.

Answer 82

A drop in body temperature below that required for cellular metabolism and function, i.e. <35oC.