Aerobic/Oxidative system

Question 1

aerobic/oxidative system

Answer 1

biochemical pathway that regenerates ATP through complete oxidation of macronutrients

Question 2

diff between anaerobic and aerobic system

Answer 2

anerobic stops at glycolysis

Question 3

how does fat enter glycolysis

Answer 3

beta oxidation first

Question 4

aerobic system exercise description

Answer 4

low power and high capacity
power - 3-5min
capacity - hours

Question 5

2 steady rate limiting factors

Answer 5

fluid loss and electrolyte depleting

maintaining adequate reserves of both liver glycogen for CNS and muscle glycogen to power exercise

Question 6

what does your brain use if you dont have enough glycogen?

Answer 6

keto acids

Question 7

why can we run for a long time with the all the increase in heat

Answer 7

because we can get rid of it

Question 8

what do we use for aerobic processes

Answer 8

mitochondria

Question 9

what kind of sports are fueled by aerobic energy?

Answer 9

marathons or race across america

intense exercise beyond several minutes

Question 10

4 divisions of aerobic metabolism

Answer 10

slow glycolysis
krebs citric acid cycle
beta oxidation
electron transport chain

Question 11

what kind of phosphorylation is ATP generated through in aerobic metabolism?

Answer 11

oxidative

Question 12

why is it called the oxidative phosphorylation?

Answer 12

because oxygen is the ultimate acceptor of electrons

Question 13

two locations for mitochondria within a muscle fibre

Answer 13

interfibrillar - energy for contraction

sarcolemmal - energy for transport

Question 14

fast twitch fibre and mitochondria

Answer 14

doesn’t have much because it needs ATP a lot faster

Question 15

slow twitch fibres and ATP rate

Answer 15

slower because we dont need it for a while

Question 16

substrates for aerobic

Answer 16

carbs, fat, sometimes proteins

Question 17

Carb storage

Answer 17

glycogen

Question 18

where do you find glucose

Answer 18

around the blood stream

Question 19

why dont we use protein for substrates for aerobic?

Answer 19

because it functions as other things

Question 20

mitochondria DNA is only from

Answer 20

mother

Question 21

folds of the mitochondria is for

Answer 21

more ball and stalk complexes for ETC

Question 22

cristae

Answer 22

space between inter and outer membrane of mitochondria

Question 23

what is formed in aerobic glycolysis and where does it go?

Answer 23

pyruvate - shuttled into mitochondrial intermembrane space via a monocarbocylate transporter (MCT)

Question 24

Pyruvate converted into

Answer 24

acetyl - CoA by pyruvate dehydrogenase complex (three enzyme complex in the inner membrane) then released into mitochondrial matrix
produces a CO2 and NADHH
Pyruvate + NAD+CoA = acetyl CoA + Co2 + NADHH

Question 25

does the formation of acetyl CoA utilize O2?

Answer 25

no but must be aerobic

Question 26

where does formation of acetyl coA occur

Answer 26

mitochondrial matrix

Question 27

products from the 2 formation of acetyl coA

Answer 27

2 NADHH
2 CO2
2 acetyl CoA

Question 28

path of NADHH from glycolysis

Answer 28

enters the mitochondria via MALATE ASPARTATE shuttle or the GLYCEROL PHOSPHATE shuttle

Question 29

NADHH in your heart

Answer 29

malate aspartate shuttle - hydrogens from NADHH passed to malate then passed to NAD

Question 30

NADHH in your muscles

Answer 30

glycerol phosphate shuttle - hydrogens from NADHH passed to glycerol phosphate then passed to FAD

Question 31

What can the accumulated lactate from anaerobic glycolysis do?

Answer 31

converted back to pyruvate via LDH h and enter mitochondrial matrix via pyruvate dehydrogenase complex (converted into acetyl coa)

Question 32

where does NADH go?

Answer 32

ETC

Question 33

where does the krebs cycle happen?

Answer 33

take place in the mitochondrial matrix

Question 34

why is the krebs cycle called a cycle

Answer 34

oxaloacetate is combined with acetyl coA to form citrate is regenerated after the oxidation of acetyl coA

Question 35

Products of the krebs sycle

Answer 35

NADH2 and FADH2

ATP/guanosine triphosphate - substrate level phosphorylation

Question 36

rate limiting enzyme of the krebs cyle
activation?
neg fdbk?

Answer 36

isocitrate dehydrogenase
ADP, Pi, Ca
ATP

Question 37

does the krebs cycle use O2

Answer 37

not directly but must be aerobic

Question 38

where does the krebs cycle occur?

Answer 38

mitochondrial matrix

Question 39

products of mitochondiial matrix (#s)

Answer 39

2 ATP
6NADH2
2 FADH2
4 CO2

Question 40

ETC

Answer 40

electron transport chain

final metabolic pathway in aerobic metabolism

Question 41

ETC location and structure

Answer 41

ball and stalk complex along the inner mitochondrial membrane
series of electron carriers and proton pumps (complex 1-4)

Question 42

ETC utilizes

Answer 42

NADH2 and FADH produced in glycolysis and krebs cycle

electrons from H are used to drive the movement of H into intermembrane space

Question 43

FADH2 vs NADH2

Answer 43

FADH 2 enters ETC at complex 2 so produced less ATP relative to NADH2

Question 44

why do you want to pump H outside?

Answer 44

to make an electrochemical gradient to drive ATP synthesis through ATP synthase (ADP+Pi = ATP)

Question 45

final electron acceptor of ETC

Answer 45

oxygen + 2e = oxygen + 2H = H2O

Question 46

rate limiting enzyme of ETC

activation and negative fdbk

Answer 46

cytochrome oxidace (complex 4) catalyzes the final transfer of electron to oxygen

ADP
ATP

Question 47

ETC and O2

Answer 47

directly utilize O2 as final electron acceptor

Question 48

location of ETC

Answer 48

inner mitochondrial membrane

Question 49

how many steps does NADHH goes through vs FADH2

Answer 49

3 and 2

Question 50

what kind of athletes has more mitochondria?

Answer 50

mitochondrial miogenesis in aerobic athletes

Question 51

theoretical ATP yield for NADH2 and actual yield

Answer 51

3 and 2.5

Question 52

theoretical ATP yield for FADH2 and actual yield

Answer 52

2 and 1.5

Question 53

why does the heart muscle produce more total ATP than skeletal muscle/glucose

Answer 53

heart uses malate aspartase which you get two of in glycolysis

Question 54

muscle glucose ATP calculation

Answer 54

glycolysis - 2ATP 
2FADH*1.5 =3 ATP 
pyruvate to acetyl coA = 2 NADH *1.5 = 5 ATP 
krebs cycle = 2ATP 
6 NADH *2.5 = 15 ATP 
2 FADH2 (1.5) = 3 ATP 
total of 30

Question 55

can fat be metabolized with out oxygen

Answer 55

no, it must go through aerobic metabolism

Question 56

fat can be obtained from 3 sources

Answer 56

intramuscular triaculglycerols (glycerol and 3 FA)
circulating triaculglycerols
mobilized from circulating free FAs (attached to albumin) mobilized from triaculglycerols in adipose tissue

Question 57

why is more oxygen required for fat oxidization?

Answer 57

fat has a higher ratio of carbon to oxygen

- more work to break down fat

Question 58

aerobic athletes and fat

Answer 58

a lot of fat in their muscles

Question 59

triaculglycerols - triglycerides

Answer 59

chains of carbons

Question 60

function of hormone sensitive lipase

Answer 60

breakdown of triacylglycerols

Question 61

function of lipoprotein lipase

Answer 61

on cell membranes - take an FA from circulating and use it

Question 62

FA in the sarcoplasm are activated using

Answer 62

activated using coenzyme A and ATP

which degrades into AMP so 2 ATP is invested to activate FA

Question 63

What happens after fat is activated

Answer 63

fatty acetyl coA shuttled into mitochondria via carnitine shuttle (intermembrane then matrix of mitochondria) to go into beta oxidation

Question 64

beta oxidation

Answer 64

cyclic series of steps that breaks off successive pair of carbon atoms from FFA, then used to make acetyl coA

Question 65

cycles of beta oxidation depends on and produces?

Answer 65

number of carbons present in FA, each produces 1FADH2 and 1 NADH
n/2-1 cycles

Question 66

16 carbon fat how many cycles?

Answer 66

7

Question 67

what does fat do after beta oxidation?

Answer 67

into the krebs cycle as acetyl coA, 1FADH, 3NADH2 and 1 ATP

Question 68

does beta oxidation need o2?

Answer 68

no but must be aerobic

Question 69

where does beta oxidation happen?

Answer 69

mitochondrial matrix

Question 70

what recycles in beta oxidation

Answer 70

acetyl coa, FADH2 and NADH

Question 71

How many ATP do we need to invest for beta oxidation and where?

Answer 71

2 in the cytoplasm

Question 72

location of carnitine

Answer 72

skeletal muscle - 95%, 20g

Question 73

carnitine function 2

Answer 73

transport of long chain FF from cytoplasm to mitochondria

helps to buffer increases in exercise induced acetyl coA

Question 74

purported benefit of carnitine supplementation

Answer 74

increased FA transport into mitochondria leading to increased FA oxidation and reduced demand on carb stores

Question 75

effectiveness of carnitine (3)

Answer 75

plasma concentration increases by 30-70%
2wks to 3m has not been demoed to increase muscle concentration - probably lost in urine
no clear evidence that supplementation enhances fat oxidation, reduces carb oxidation, glycogen breakdown or lactate accumulation , enhance performanc of increase VO2 max

Question 76

How does fat burn in the flame of carbs?

Answer 76

oxaloacetate in the kreb’s cycle is produced from pyruvate and it needs to be present for acetyl coA to enter the krebs cycle

Question 77

in the absence of carbs, energy production

Answer 77

slows - bonking/hitting the wall

Question 78

why arent proteins a significant source of energy during exercise

Answer 78

importatn structural and functional role

Question 79

How do AAs get turned into pyruvate, acetyl coA and krebs cycle intermediates

Answer 79

deamination (removal of NH2) and transamination (transfer of NH2 to another substrate)

Question 80

How many AAs are there and what numbers enter the cycle as what?

Answer 80

6 entered at pyruvic acid 
8 at acetyl coa 
4 at alpha ketoglutarate 
4 at succinate 
2 at oxaloacetate

Question 81

gluconeogenesis (3)

Answer 81

ensures that the brain, nerves, and kidney and muslces have a source of carb to draw from
creation of glucose in the liver from non carb sources
glycerol (glycerol glucose cycle)
lactate/pyruvate (cori cycle)
alanine (felig cycle)

Question 82

ketones

Answer 82

in the absense of glycogen, metabolism switches to the prodcution of ketone bodies 
liver converts acetyl coA into 
-acetoacetic acid 
-beta hydroxybutyric acid
-acetone

Question 83

why are ketones produced

Answer 83

sparse glucose for the brain and NS

Question 84

side effect of ketones

Answer 84

strong acids - contribute to ketoacidosis if high enough

Question 85

utilization of ketones as a fuel source

Answer 85

atheletes/ trained atheletes

Question 86

why is cars the preferred substrate for aerobic system

Answer 86

uses the least amt of o2

Question 87

glycogen vs glucose ATP

Answer 87

glycogen uses one more ATP

Question 88

aerobic system energy supply ranked in amount

Answer 88

triglycerides
muslce glycogen
liver glycogen
circulating glucose

Question 89

least fat percentage to survive

Answer 89

3.5

Question 90

why do we consume energy before and during a marathon

Answer 90

glycogen stores but we dont sore enough so we use fat, but to use fat we need carbs

Question 91

What controls the SNS

Answer 91

hypothalamas

Question 92

What SNS controls blood glucose (2)

Answer 92

insulin and glucagon through SNS, adrenal medulla then E and NE for pancreas for insulin and glucagon.

Question 93

glucagon effect on metabolism during exercise (6)

Answer 93

decrease glucose uptake and utilization 
increase glycogen breakdown 
decrease glycogen formation 
increase gluconeogensis
decrease FFA storage and increase FFA mobilization

Question 94

E and NE effect of metabolism during exercise (4)

Answer 94

increase glycogen breakdown
decrease glycogen formation
increase gluconeogensis
FFA mobilization

Question 95

growth hormone and cortisol effect of metabolism during exercise

Answer 95

decreased glucose uptake and utilization 
increase glycogen breakdown 
increase glycogen formation 
increased gluconeogenesis 
decreased FFAstorage 
Increased FFA mobilization 
increased AA transport and uptake 
increased protein breakdown for only cortisol

Question 96

why do growth hormone and cortisol increase glycogen formation

Answer 96

long term hormones that think that we need to be prepared for the next time this happens

Question 97

4 hormones that limit glucose uptake by things other than muscles

Answer 97

E/NE, Glucagon, cortisol, growth hormone

Question 98

sex differences in fuel utilization

Answer 98

males use more carbs than females because we use more glucose because of our different hormone profiles lets us oxidize diff substrates

Question 99

VO2 max

Answer 99

maximal oxygen consumption - highest amt of oxygen an ind can take in, transport, and utilize to produce ATP aerobically while breathing air during heavy exercise

Question 100

when does VO2max occue?

Answer 100

when oxygen uptake plateaus/increase only slightly with additional increases in exercise intensity

Question 101

what does VO2max require

Answer 101

integrated and high level responses of 5 diverse physiological support systems

Question 102

VO2max provides a _______ measure of?

Answer 102

quantitative measure of a person’s capacity for sustained aerobic ATP resynthesis
- ability to maintain intense exercise for longer than 4/5 mins

Question 103

high VO2 max decreases the risk of

Answer 103

CV disease

Question 104

Genetics and sex difference of VO2 max

Answer 104

50-80% genetically determined

males are higher

Question 105

will a high VO2 win everything?

Answer 105

not if he doesnt train properly

Question 106

two physiological things needed for high VO2

Answer 106

high cardiaxc output and good peripheral bloodflow and some to constrict

Question 107

as you age what happens to your VO2max?

Answer 107

drops

Question 108

VO2 max related to 2

Answer 108

heart size and hemoglobin concentration

Question 109

VO2max on mount everest

Answer 109

25%

Question 110

direct tests for anaerobic power/VO2max

Answer 110

incremental exercise through metabolic cart
- lab systems
- protable systems
douglas bags

Question 111

indirect submaximal tests for Aerobic power/VO2max (3)

Answer 111

YMCA cycle ergometer test
ebbeling single stage treadmill walking test
modified canadian aerobic fitness test

Question 112

indirect maximal test for VO2 max (anaerobic power)

Answer 112

bruce treadmill test - increments of intensity and see how long you go for
leger 20m shuttle test (incremental)
cooper 12 minute test (cooper)

Question 113

what do indirect VO2 tests usually look at

Answer 113

HR, age, formula

Question 114

anaerobic threshold/aerobic capacity

Answer 114

VO2 at which energy production supplements the aerobic capacity - % of VO2 max/absolute workload

Question 115

measuring aerobic capacity and its two thresholds

Answer 115

incremental test to volitional max
lactate threshold 1 (LT1) between 40-60% 2mM
lactate
lactate threshold 2 (LT2)/lactate turnpoint is above 80% threshold and possibly up to 95 4mM

Question 116

LT2 (3)

Answer 116

onset of blood lactate accumulation
good approximation of maximal lactate steady rate
above MLSS exercise will terminate

Question 117

maximum lactate steady rate (2)

Answer 117

highest workload that can be maintained overtime without a continual rise in blood lactate (lactate production=lactate clearance)
endurance exercise cannot be completed above the MLSS, but portions of the exercise can take place above this level

Question 118

criteria of MLSS

Answer 118

in a 30 min test blood lactate cannot change more than 1mM over the last 20 min of the test

Question 119

order of zone of occurance on a chart of lactate vs power

Answer 119

100 watt 
steady over course of exercise 
250 watts 
exceed MLSS 
failure zone 
375

Question 120

4 reasons why does anaerobic system start supplementing aerobic metabolism when oxygen intake is not at VO2 max

Answer 120

• increased recruitment of fast twitch motor units which have a greater reliance of glycolysis
• increased SNS tone - stimulate glycogenolysis
• blood stunt mechanism - vaso constriction to less tissue, resulting in enhanced accumulation of lactate and reduced clearance
• hypoxia? not likely because operating at 70% VO2max

Question 121

increased intensity means

Answer 121

increased o2 consumption

Question 122

oxygen uptake during exercise

Answer 122

initailly rises exponentially before it plateaus, then remains a steady rate for the duration of the effoert

Question 123

oxygen deficit

Answer 123

difference between the o2 required during exercise and O2 supplied and utilized, occurs at onset of all activity

Question 124

The energy that cannot be supplied through aerobic metabolism at the initiation of submaximal exercise is supplied by?

Answer 124

ATPPC and anaerobic glycolytic energy systems, eventually if the intensity is submaximal the oxygen deficit is nullified once steady state VO2 is achieved

Question 125

Causes of oxygen deficit

Answer 125

central factors - O2 delivery to muscle - inability to circulatory and respiratory systems to deliver enough oxygen to meet energy demands
peripheral factors : O2 utilization by muscles - slow intracellular metabolic activation - metabolic inertia
* limited cellular utilization of O2 as a result of adjustments in both anerobic and aerobic systems, the metabolic systems simply respond at diff speeds - ca released activates the systems then ATPPC, ADP and inorganic phosphate triggers anaerbic glycolysis to work faster

Question 126

why is it beneficial to get to steady state asap?

Answer 126

so that metabolic products dont accumulate

Question 127

oxygen deficit is reduced through

Answer 127

aerobic
adequate warm up
- elevate muscle temp which increases the rate at which the metabolic processes in the cells can proceed

Question 128

what can decrease oxygen deficit

Answer 128

training

Question 129

10 metabolic adaptations to aerobic training

Answer 129

increased glycogen storage (muscle and liver)
increased mobilization and transportation of fats, which spares muslce glycogen
increased myoglobin to increase amt of o2 in muslce
increased capillarization to increase influx of substrates and removal of metabolic waste
increased size and number of mitochondria (mitochondrial biogenesis) and associate enzymes
increased beta oxidation at the same absolute and relative submaximal workload
decreased lactate accumulation at the same absolute and relative submax workload
increased MCT1 lactate transporters
increased LDHh activity
increased max oxygen consumption

Question 130

alactic power, capacity, intensity for power and intensity for capacity

Answer 130

0.1-3 (5)
8-12 (15)
explosive
all out

Question 131

lactic, capacity, intensity for power and intensity for capacity

Answer 131

15-30
45-120
all out
all out

Question 132

aerobic power, capacity, intensity for power and intensity for capacity

Answer 132

3-5min
hours
near max to max at end
submax

Question 133

energy activation for exercise

Answer 133

smooth blending with considerable overlap of one mode to another

Question 134

accepted explanation of O2 deficit

Answer 134

byproducts of additional energy use ADPP and NADHH to stimulate both aerobic and anaerobic metabolism (order of operations)