test 2

Question 1

What are the 4 methods of heat transfer?

Answer 1

Conduction
convection
thermal regulation
evaporation

Question 2

Conduction

Answer 2

loss or gain

Question 3

convection

Answer 3

loss or gain

Question 4

thermal regulation

Answer 4

loss or gain

Question 5

evaporation

Answer 5

loss

Question 6

conduction rate of transfer determined by

Answer 6

1. Temperature gradient
2. Distance between core and environment
3. Conductivity of the material between core and environment

Question 7

convection rate of transfer determined by

Answer 7

1. Temperature gradient
2. Air/fluid speed
3. Shape/diameter of body parts

Question 8

involves contact between solid objects to move heat

Answer 8

conduction

Question 9

wave length _____ as temperature ____

Answer 9

Decreases, increases

Question 10

A potential mechanism for cooling without water loss

Answer 10

thermal radiation

Question 11

thermal radiation Rate of heat transfer determined by?

Answer 11

Surface temperature

Emissivity of the surface

Question 12

Radiation may be _____, ______, or _____

Answer 12

absorbed, reflected or pass through

Question 13

Heat moves from ____ temperature to ____ temperature

Answer 13

high temperature to low temperature

Question 14

Objects receiving the heat _____ in temperature, objects losing heat _____ in temperature

Answer 14

increase, decrease

Question 15

Thermal equilibrium occurs when?

Answer 15

both objects are at the same temperature and there is no net movement of heat

Question 16

Animals may gain and lose heat _____

Answer 16

simultaneously

Question 17

Transfer of heat between neighboring molecules due to a temperature gradient

Answer 17

conduction

Question 18

Transfer of heat through a substance due to visible movement of the substance

Answer 18

convection

Question 19

Much faster than conduction

Answer 19

convection

Question 20

Highly effective cooling mechanism

Answer 20

evaporation

Question 21

Conversion of body water from the skin and respiratory tract to gas requires substantial amounts of heat energy

Answer 21

evaporation

Question 22

warmed by the metabolic production of heat

Answer 22

Endothermy

Question 23

maintenance of a relatively constant body temperature

Answer 23

Thermoregulation

Question 24

Environmental temperature

Answer 24

Determines metabolic rate and therefore how much food is required

Question 25

Body temperature

4

Answer 25

• Regulates tissue function
• Balance of heat input versus heat output
• Heat input: metabolic heat production, from the environment, conduction, convection, radiation
• Heat output: conduction, convection, radiation, evaporation

Question 26

Poikilotherms are also called ____

Answer 26

ectotherms

Question 27

fish, reptiles, amphibians are examples of ?

Answer 27

ectotherms

Question 28

Body temperature is dependent on environmental temperature

Answer 28

ectotherms

Question 29

mammals, birds, some insects

Answer 29

homeotherms

Question 30

Can also alter behavior to influence heat dissipation

Answer 30

homeotherms

Question 31

Thermoregulate by physiological means

Answer 31

homeotherms

Question 32

Mammals maintain their body temperatures within a very narrow range called

Answer 32

“Set point”

Question 33

Skin thermoreceptors: (3)

Answer 33

• Skin in contact with environment
• Skin temperature changes before core temperature
• “warning system”- modify the set temperature to trigger a thermoregulatory response before core temperature changes

Question 34

Core thermoreceptors: (3)

Answer 34

• Hypothalamus (brain)
• Receive inputs from skin thermoreceptors
• Generate the response

Question 35

How is body temperature monitored and regulated?

Answer 35

skin and core thermoreceptors

Question 36

Thermoneutral zone:

Answer 36

the range of environmental temperatures where animals can maintain core body temperature without an increase in metabolic rate

Question 37

DOES NOT REQUIRE ENERGY THEREFORE DOES NOT AFFECT THE METABOLIC RATE (energy req’t)

Answer 37

Insulation

Question 38

Vasomotor responses

Answer 38

• (physiological)
• Vasoconstriction/vasodilation to alter blood flow to the skin
• Insulation

Question 39

Postural responses

Answer 39

• (behavioral)
• Controlling amount of surface area exposed to ambient temperatures
• Insulation

Question 40

Erection or compression of hair (pilomotor response) or feathers (ptilomotor response)

Answer 40

• (physiological)
• Greater erection = greater insulation = greater resistance to heat loss
• Insulation

Question 41

Resistance to heat loss through conduction, convection and radiation

Answer 41

Insulation

Question 42

Body temperature maintained by ?

Answer 42

mediating the degree of insulation

Question 43

Width of TNZ is determined by the extent to which the ?

Answer 43

animal can mediate their insulation

Question 44

Shivering

Answer 44

• (physiological)
• Uncoordinated contraction/relaxation of muscles
• ATP ultimately becomes heat

Question 45

Non-shivering thermogenesis

Answer 45

-(physiological)
-Heat production without shivering
fat oxidation can occur quickly, but energy released directly as heat
-Primarily mammals and young birds
Cold-acclimated adults, hibernators, newborns
Brown adipose: high vascularity, large mitochondria, well innervated; uncoupling protein 1 expression

Question 46

Below the thermoneutral zone

Answer 46

ATP requiring = INCREASED METABOLIC RATE

Question 47

Responses to temperatures above the upper critical temperature

Answer 47

• Energy requiring processes- ↑ metabolic rate

- Initiation of evaporative cooling

Question 48

Energy requiring processes to increase evaporative loss =

Answer 48

INCREASE METABOLIC RATE

Question 49

Sweating:

Answer 49

• in some mammals; sweat secreted to the surface of the skin
• (physiological)

Question 50

Panting:

Answer 50

• increased rate of breathing

- (physiological)

Question 51

Gular fluttering:

Answer 51

• in birds; vibrating the floor of the oral cavity to increase airflow over mucous membranes
• (physiological)

Question 52

Pyrogens (cytokines, prostaglandins) cause an _____ in the body’s “set-point”

Answer 52

increase

Question 53

Pyrogens

Answer 53

• Trigger to conserve heat and produce more heat to reach new set point
• Shivering, vasoconstriction, piloerection, etc.
• Increase in body temperature

Question 54

Three types of muscle

Answer 54

• cardiac
• Skeletal
• smooth

Question 55

Skeletal muscle

Answer 55

• Striated muscle associated with voluntary movement

- Contraction is regulated by the somatic nervous system

Question 56

Cardiac muscle

Answer 56

• Striated muscle in the heart

- Contraction regulated by the autonomic nervous system

Question 57

Smooth muscle

Answer 57

• Muscle in blood vessels, visceral tissues

- Contraction is regulated by the autonomic nervous system

Question 58

3 layers of connective tissue membranes:

Answer 58

• Epimysium: layer of cells encasing entire muscle
• Perimysium: layer of cells encasing a bundle (fascicle) of muscle fibers (muscle cells)
• Endomysium: layer of cells encasing individual muscle fibers

Question 59

Multi-nucleated =

Answer 59

each cell has more than one nucleus

Question 60

Sarcoplasmic reticulum- surround _____

Answer 60

individual myofibrils

Question 61

Sarcolemma =

Answer 61

• cell membrane of individual muscle fibers
• Plasma membrane
• Outer membrane of polysaccharide and collagen
• Invaginations = T-tubules
• Has acetylcholine receptors and ion channels

Question 62

A strand of interacting proteins (actin + myosin) that runs parallel to the length of the muscle

Answer 62

Myofibrils

Question 63

Repeating unit that forms the myofibrils =

Answer 63

sarcomere

Question 64

sarcomere

Answer 64

• Contractile unit
• Each sarcomere shortens during muscle contraction
• Net effect = entire muscle fiber shortens

Question 65

Individual sarcomeres separated by

Answer 65

Z-disks

Question 66

sarcomeres Composed of ?

Answer 66

• myofilaments (proteins)
• Thick (myosin)
• Thin (2 actin chains, troponin, tropomyosin)

Question 67

Thick filament

Answer 67

Myosin molecules arranged to have “head” and “tail” regions

Question 68

Thin filament

Answer 68

• Actin chain
• Troponin
• Tropomyosin

Question 69

Flexion

Answer 69

Decreases joint angle

Question 70

Extension

Answer 70

Increases joint angle

Question 71

Whole-muscle contraction

Answer 71

Distance between insertion (end of the muscle that attaches to the freely moving bone) and origin (end of muscle that attaches to the “fixed” bone in the joint) shortens

Question 72

The sarcomere shortens because there is a ?

Answer 72

greater degree of overlap between the thick and thin filaments

NONE of the individual filaments changes in length

Question 73

“Sliding filament theory”:

Answer 73

thick and thin filaments slide over each other, increasing the degree of overlap

Question 74

Muscle contraction needs:

Answer 74

• ATP
• nerve impulse (acetylcholine)
• calcium

Question 75

_____ is needed to separate actin from myosin from the previous contraction cycle

Answer 75

ATP

Question 76

Myosin ATPase cleaves ______

the energy is not used until calcium is present

Answer 76

ATP to ADP + Pi

Question 77

_____ binds _____, allowing myosin to bind to actin

Answer 77

Calcium, troponin

Question 78

The Pi group is released and the stored energy is used to

Answer 78

flex the myosin head, pulling the thin filament over the thick filament, towards the M-line

• Powerstroke
• ADP is eventually released
• Cycle repeats itself as ATP binds to the myosin head

Question 79

Troponin

Answer 79

• Attached to actin filaments and tropomysin

- Has a binding site for calcium, which influences how it interacts with tropomyosin

Question 80

Tropomyosin

Answer 80

• No Ca2+ = blocks myosin binding site on actin

- Ca2+ = moves off the myosin binding site on the actin

Question 81

Ca2+ enters the cytoplasm due to

Answer 81

nerve stimulation

Question 82

Excitation-Contraction coupling

Answer 82

• Relationship between membrane depolarization and contraction
• Link between nervous and musculoskeletal systems

Question 83

T-tubules of the sarcolemma

Answer 83

• Membrane “dips” into the cytoplasm (sarcoplasma) perpendicular to the fibers
• Has ion channels
• Allows membrane depolarization to be “experienced” deep in the muscle fiber

Question 84

Sarcoplasmic reticulum

Answer 84

• Surround each myofibril
• Sequester and release Ca2+ upon membrane (t-tubule) depolarization (Ach binding receptors on sarcolemma)
• Terminal cisternae- part of the SR near the t-tubules and store calcium ions

Question 85

Membrane calcium channels

2 voltage-gated calcium channels

Answer 85

• T-tubules: DHPRs (dihydropyridine receptor)

- Sarcoplasmic reticulum: RyR (ryanodine receptor)

Question 86

ATP needed for:

Answer 86

• ATP binding to cross-bridge: myosin detaches from actin- prevent rigor mortis
• ATP hydrolysis: energy needed for the “power stroke”
• Drives the Ca2+ pump to return calcium to the sarcoplasmic reticulum

Question 87

Twitch fibers

Answer 87

• generate action potentials

- Most common

Question 88

Classified based on myosin ATPase type (how fast myosin ATPase can cleave myosin; speed of contraction)

Answer 88

• I: Slow oxidative
• IIA: Fast oxidative glycolytic
• IIB/IIX: Fast glycolytic

Question 89

What is a nervous system?

Answer 89

• A network of neurons and support (glial) cells
• Signals pass from sensory receptors/neurons, are integrated, new signals are generated and conducted through neurons to the effector cells
• A regulatory system

Question 90

What does the nervous system help animals do?

Answer 90

-Regulate muscle contraction → regulate movement

Regulate secretions from glands → hormone, enzymes, saliva, etc.

Gather information about the external and internal environment → maintain homeostasis

Detect pain, pressure, chemical concentrations
Stimulate thirst, hunger and other survival mechanisms

Question 91

CNS =

Answer 91

interneurons

• brain
• spinal cord

Question 92

Continues caudally from the brainstem

Answer 92

spinal cord

Question 93

Encapsulated by the vertebrae

Answer 93

spinal cord

Question 94

spinal cord has 2 types of neural circuits

Answer 94

1. Local
   - Sensory neurons, interneurons and motor neurons all in the same segment
   - Control the output of that segment
   - Primitive reflexes
2. Ascending/Descending
   - Communication to/from the brain for higher integration

Question 95

Peripheral nervous system

Answer 95

Any nervous tissue located outside of the brain and spinal cord

Sensing the environment

Activating tissue/organ responses

Question 96

Peripheral nervous system, 2 key divisions:
Somatic
Autonomic

Answer 96

• Somatic

- Autonomic

Question 97

Central nervous system:

Answer 97

includes brain and spinal cord

Question 98

Peripheral nervous system:

Answer 98

neurons going to and from the CNS

Question 99

Afferent neurons:

Answer 99

conduct “signal” towards the CNS (sensory neurons)

Question 100

Efferent neurons:

Answer 100

conduct “signal” away from the CNS (motor neurons)

Question 101

Interneurons:

Answer 101

entirely within the CNS

Question 102

Cell that is able to generate and propagate an electrical signal

Answer 102

neuron

Question 103

4 key parts of the neuron:

Answer 103

Dendrites- Input

Cell body (soma)- Integration (processing)

Axon- Transmission

Pre-synaptic terminals (telodendrion)- Output

Question 104

Neurons generate signals that are ____ and ____

Answer 104

fast, addressed

Question 105

electrical signals are faster than _______ signals

Answer 105

hormonal

Potential to conduct 100 impulses per second

Question 106

Cell body (stoma)

Answer 106

Nucleus containing

Processes emanate outwards

Organelles: mitochondria, golgi apparatus, endoplasmic reticulum (rough and smooth)

Active in protein synthesis (neurotransmitters)

Question 107

Dendrites

Answer 107

• Short, branch repeatedly
• Dendritic spines
• Similar organelles to the stoma

Question 108

Axon

Answer 108

Generally 1 per neuron

May or may not be myelinated

Contain mitochondria and smooth endoplasmic reticulum

Question 109

Axon terminals

Answer 109

Branches off the end of the axon

Contain vessicles of neurotransmitters (made in stoma)

Axoplasmic transport

Site of neurotransmitter release

Question 110

Glial cells

Answer 110

Cells in the nervous system that support neural function

Question 111

Outnumber neurons ~10:1

Answer 111

Glial cells

Question 112

Glial cells Different types (3)

Answer 112

Schwann cells (PNS)/Oligodendricytes (CNS): form myelin sheath (wrap around axons)

Astrocytes (CNS): metabolic support cells, intermediate between neuron and capillary

Microglial cells (CNS): immune function

Question 113

Tract:

Answer 113

bundle of myelinated axons in the CNS

Question 114

Nuclei:

Answer 114

groups of nerve cell bodies in the CNS

Question 115

Grey matter:

Answer 115

cell bodies, synapses, unmyelinated axons

Question 116

White matter:

Answer 116

• tracts of myelinated axons

- Ascending and decending

Question 117

outside of brain, inside of spinal cord

Answer 117

grey matter

Question 118

inside of brain, outside of spinal cord

Answer 118

white matter

Question 119

Nerve: a bundle of neuron axons in the peripheral nervous system
Cranial nerves
Spinal nerves

Answer 119

-a bundle of neuron axons in the peripheral nervous system

• Cranial nerves
• Spinal nerves

Question 120

Ganglion:

Answer 120

a grouping of nerve cell bodies in the peripheral nervous system

Question 121

Three key things contribute to the resting membrane potential:

Answer 121

Na+/K+ pump

Ion separation and ions will move toward their equilibrium (inside of the cell also has more proteins with a negative charge that cannot diffuse through the membrane, so even if K+ and Na+ move in and out to try to reach equilibrium, they

Differential membrane permeability (more K+ leakage channels and so K+ is more likely to reach equilibrium because it can move more freely through the membrane, so the resting membrane potential is closer to the K+ potential than the Na+ potential)

Question 122

Resting membrane potential =

Answer 122

-65 mV

Question 123

Na+ membrane equilibrium potential =

Answer 123

+58 mV

Question 124

K+ membrane equilibrium potential =

Answer 124

-80 mV

Question 125

Factors that maintain resting membrane potential:

Answer 125

• ions must pass through membrane channels or be actively transported
• Different membrane channels are permeable to different ions
• Selective permeability
• Membrane channels may open and close
• Not all channels are necessarily open/closed at the same time
• Different ions can move through the membrane at different times

Question 126

Maintaining ion concentration differences at rest

Answer 126

• Maintained by the Na+/K+-ATPase pump
• 3 Na+ out, 2 K+ in
• Neither K+ or Na+ is in electrochemical equilibrium

Question 127

Membrane is more permeable to ___ than ___

Answer 127

K+ than Na+

Question 128

_______% of ATP produced in the brain from glucose is used for Na+/K+-ATPase pump function

Answer 128

50 – 70%

Question 129

Something that _____ the membrane, makes the membrane potential greater than -65 mV

Answer 129

depolarizes

Question 130

Something that _____ the membrane makes the membrane potential less than -65 mV

Answer 130

hyperpolarizes

Question 131

What is an action potential?

Answer 131

Electrical signal generated by excitable cells due to voltage-dependent changes in membrane permeabilitie

Question 132

action potential is triggered by ?

Answer 132

Triggered by depolarization (to ~-55 mV)

Question 133

Action potentials are an _____ phenomenon

Answer 133

‘All or None’

Question 134

Changes in ______ create action potentials

Answer 134

membrane permeability

Question 135

Lidocaine =

Answer 135

local anaesthetic

Question 136

Lidocaine “blocks”______channels

Answer 136

voltage-gated Na+

Question 137

Downstream =

Answer 137

action potential possible

Question 138

Upstream =

Answer 138

no action potential possible

Question 139

Factors controlling action potential velocity (speed) (3)

Answer 139

axon diameter

temperature

mylionation

Question 140

Factors controlling action potential velocity (speed)

Axon diameter

Answer 140

• ↑ action potential velocity with ↑ increased diameter
• More ion channels per unit length with increasing diameter = less resistance to ion flow into the axon = easier to depolarize

Question 141

Factors controlling action potential velocity (speed)

Temperature

Answer 141

• Ion channels are temperature dependent
• Increasing temperature exponentially increases conduction velocity
• Warm blooded animals (vs. reptiles) can maintain a high conduction velocity without having large diameter neurons

Question 142

Factors controlling action potential velocity (speed)

Myelination

Answer 142

• ↑ action potential velocity
• Action potential “jumps” from Node of Ranvier to Node of Ravier- Saltatory conduction

-Myelin = insulates the axon
No ions can move in/out portions of the axon where there is the myelin wrapped around

-Only need to depolarize the Node of Ranvier regions, which is a relatively small portion of the axon, therefore speed is much faster in myelinated axons than unmyelinated axon

Question 143

What is a synapse? (5)

Answer 143

Contact between a neuron and another neuron or a neuron and its effector cell

Pre-synaptic neuron (axon)

Post-synaptic neuron (dendrite or cell body) OR a cell (ie. muscle)

Cells separated by the synaptic cleft

Communication occurs via neurotransmitters

Question 144

What makes it a neurotransmitter?

Answer 144

Chemical compound present in the pre-synaptic terminal

Released upon stimulation (depolarization and calcium)

Interacts with the receptors on a post-synaptic cell

Question 145

Properties of chemical synapses

Fast =

Answer 145

ionotropic

Question 146

Properties of chemical synapses

Slow=

Answer 146

metabotropic

Question 147

Properties of chemical synapses

Answer 147

Unidirectional

Uses neurotransmitters

Two classifications

• slow (metabotropic)
• fast (ionotrpoic)

Can be excitory (cause depolarization) or inhibitory (cause hyperpolarization)

Question 148

Ionotropic (5)

Answer 148

receptor ligand-gated channel

Directly alter membrane permeability to ions (open/close ion channels)

Signal transduction

Fast

Excitory (depolarizes) and Inhibitory (hyperpolarizes) effects

Question 149

Metabotropic

Answer 149

Receptor: G-coupled protein receptor

Produce a metabolic change in the post-synaptic cell (usually with secondary messengers)

Modulation of neuronal function

Slow

Excitory (indirect), Inhibitory (indirect) and other (cytoplasmic, gene expression, enzymatic) effects

Question 150

Neurotransmitter released into

Answer 150

synaptic cleft

Question 151

Neurotransmitter is synthesized in ________ cell

Answer 151

pre-synaptic cell

Stored in vesicles at either the active site or interior of axon terminal

Question 152

Each vesicle contains _____ neurotransmitter molecules

Answer 152

~5,000

Question 153

neuro transmitter Release requires _____ and ______

Answer 153

membrane depolarization and calcium influx