Cardiac Rehabilitation Flashcards

Question 1

Q

What is the definition of health?

Answer

A

“A state of complete physical, mental and social well-being and not merely the absence of disease or infirmity” (p 1. W.H.O., 1947)

Question 2

Q

What did Bouchard et al. (2007) show?

Answer

A

That there is a complex interaction between health, physical activity and physical fitness. There are important determinants from heredity, lifestyle and environment.

Question 3

Q

Which key studies give evidence of lower mortality in more physically active and / or higher fit people?

Answer

A

• Harvard Alumni Health Study 1986: (Paffenbarger et al., NEJM, 315) + Harvard Alumni Health Study 1995: (Lee et al., JAMA, 273) • Blair et al. 1989: aerobic centre longitudinal study • Framingham study • Baugerleuser study • Zutphen elderly study & Finnish Twin Cohort

Question 4

Q

What did the Harvard Alumni Health Study 1986: (Paffenbarger et al., NEJM, 315) study show?

Answer

A

Mortality ↓ with ↑ physical activity 27% less risk of mortality from expending >2000kcal per week

Question 5

Q

What did the Harvard Alumni Health Study 1995: (Lee et al., JAMA, 273) show?

Answer

A

Mortality ↓ with ↑ physical activity (Confirmed the 1986 HAHS results; that less risk of mortality from expending >2000kcal per week)

Question 6

Q

How would you expend >2000kcal per week?

Answer

A

Walking at 4mph = 400Kcal ph, thus 5hrs walking per week for 2000Kcal

Question 7

Q

What did the results of the Harvard Alumni Health Studies recommend?

Answer

A

less risk of mortality from expending >2000kcal per week (Walking at 4mph = 400Kcal ph, thus 5hrs walking per week for 2000Kca)

Question 8

Q

What did the Aerobic centre longitudinal study 1989: (Blair et al., JAMA, 262) show?

Answer

A

Biggest drop in mortality moving from lowest fit (Q1) to below average fitness (Q2) 2. Low fit men have 3.3 and low fit women 4.7 X more mortality than high fit (Q5)

Question 9

Q

The combination of results from the Zutphen elderly study & Finnish Twin Cohort study + British regional heart study, • Harvard Alumni Health Study, aerobic centre longitudinal study and the study of osteoporotic fractures shows what?

Answer

A

That it is never too late for previously inactive patients to become more active as it has been shown to have an impact on their mortality risk ratio. Also that those with the lowest activity/fitness have the most to gain in terms of mortality risk when commencing PA.

Question 10

Q

What does the ACSM, 2010 evidence show?

Answer

A

A) Occupational and leisure activity: 2 X more CHD death for sedentary vs. active occupations. 2 X more CHD death for low vs. high non- occupational physical activity. B) Fitness Every 1 MET increase in aerobic fitness = 12% more survival Below 5 METs = worse prognosis

Question 11

Q

Below which MET level do you have a worse prognosis?

Answer

A

Below 5 METs

Question 12

Q

Increasing your MET by 1 improves your survival by what percentage?

Answer

A

Every 1 MET increase in aerobic fitness = 12% more survival

Question 13

Q

What is the best recommendation for occupation & leisure activity in terms of CHD death risk?

Answer

A

Active occupation + high PA outside occupation [2 X more CHD death for sedentary vs. active occupations. 2 X more CHD death for low vs. high non- occupational physical activity.]

Question 14

Q

What are the axis on the dose-response curve?

Answer

A

Y - health benefits X - activity status

Question 15

Q

What are the consequences of the dose-response curve?

Answer

A

The greatest health benefits are achieved when increasing physical activity levels from sedentary to moderately active + The more physical activity you do, the greater the health benefits – Each 10 minutes of MVPA results in 10% mortality risk reduction (RR) – Achieve 150 mins MVPA then 30-40% less RR – 750 mins MVPA (3 X recs) only increases RR to 50%

Question 16

Q

What does the dose-response curve tell us about mortality risk reduction (RR)?

Answer

A

– Each 10 minutes of MVPA results in 10% mortality risk reduction (RR) – Achieve 150 mins MVPA then 30-40% less RR – 750 mins MVPA (3 X recs) only increases RR to 50%

Question 17

Q

Is there truly a steeper relationship between fitness and relative risk than PA? And what are the consequences for public health initiatives?

Answer

A

–Likely due to measurement error in physical activity studies (Easier to objectively measure physical fitness) –Public health initiatives should target physical activity because that will increase fitness levels

Question 18

Q

What did Clarke et al, BMJ 2012 show about Olympians?

Answer

A

Olympians live 2.8 years longer on average. Thought to be due to genetics, wealth and PA throughout life. Endurance athletes had greatest benefit, but even resistance athletes benefitted.

Question 19

Q

Should you exercise even if unwell? What is the evidence?

Answer

A

Yes: Physically fit men with existing chronic conditions (e.g., CVD, HTN, DM) have a lower risk of mortality compared with men who are unfit. Hypertension High fit without HTN had 0.5 mortality risk reduction (RR) of low fit High fit with incidental (white coat) HTN had 0.4 RR of low fit High fit with history of HTN had 0.4 RR of low fit Diabetes High fit with DM had 0.5 RR of low fit without DM

Question 20

Q

For which clinical health conditions is there good evidence to suggest that being active / fit helps prevent or treat?

Answer

A

CHD, stroke, HTN, cancer, diabetes, falls, depression, dyslipidaemia. (2008 physical activity guidelines for Americans: US Dept Health and Human Services)

Question 21

Q

What are the key new points from the 2008 physical activity guidelines for Americans?

Answer

A

• VPA and MPA can be mixed up. VPA>MPA? • Fq: can spread over week/weekend warriors (but fq bouts better for DM, HTN, depression, hyperlipidaemia etc.) • Duration: 10min bouts currently recommended; but <10min still beneficial as avoids sedentary behaviours

Question 22

Q

What are the 2008 PA guidelines for American Adults?

Answer

A

Inactivity should be avoided. Some is better than none, especially in low active groups. 2. 75min VPA/week 3. Or 150 MPA/week 4. Or equivalent blend 5. At least in episodes of 10min 6. Preferably spread throughout the week 7. For extensive health benefits, 5h/week MPA 8. Or 150VPA/week 9. Or equivalent combination of MPA and VPA 10. 2x strength training moderate/high intensity per week for bone density health

Question 23

Q

What are the 2008 PA guidelines for Children?

Answer

A

Generally 1h/day MPA-VPA. 2. VPA at least 3d/wk. 3. Muscle strengthening at least 3d/wk. 4. Bone strengthening at least 3d/wk.

Question 24

Q

What is preload?

Answer

A

Preload–theamountof blood in the ventricles before contraction ♥ End diastolic volume About 100mL

Question 25

Q

What is afterload?

Answer

A

Afterload=the amount of blood left in the ventricles after contraction ♥ End systolic volume About 40mL

Question 26

Q

What is the ejection fraction?

Answer

A

SV/EDV x 100 = ((EDV-ESV) / EDV)) x 100 Approx at rest 70%

Question 27

Q

What is Q?

Answer

A

Cardiac output = HR (bpm) x SV

Question 28

Q

What is SV?

Answer

A

Stroke volume End Diastolic Volume – End Systolic volume Preload - afterload

Question 29

Q

What is shortening fraction?

Answer

A

((EDD - ESD) / EDD) x 100 Approx at rest 35%

Question 30

Q

What triggers the cardiovascular response?

Answer

A

Efferent signals: Balance between (PNS/vagus and SNS/cardiac) autonomic branches to control myocardial contraction.

Question 31

Q

Describe the sympathetic innervation of the myocardium.

Answer

A

• Sympathetic (CARDIAC) nerves innervate atria, SAN, AVN, myocardial muscle of ventricle. Release noradrenaline. [Also a direct link to adrenal gland leading to adrenaline response which acts on heart but is obviously slower.] • SNS exerts a chronotropic effect to increase HR and an ionotropic effect to increase strength of contraction.

Question 32

Q

What type of effect does the SNS have on the myocardium?

Answer

A

• SNS exerts a chronotropic effect to increase HR and an ionotropic effect to increase strength of contraction.

Question 33

Q

Describe the parasympathetic innervation of the myocardium.

Answer

A

Parasympathetic nerves (VAGUS NERVE) innervates the SAN and AVN and atria. PNS only exerts a chronotropic effect to decrease HR.

Question 34

Q

Which branch of the autonomic nervous system innervates the SAN, AVN and atria?

Answer

A

Parasympathetic nerves (VAGUS NERVE)

Question 35

Q

Which branch of the autonomic nervous system innervates the SAN, AVN and ventricles?

Answer

A

Sympathetic (CARDIAC) nerves

Question 36

Q

What effect does the PNS have on HR?

Answer

A

PNS =↓ HR

Question 37

Q

What effect does the SNS have on HR and contraction?

Answer

A

SNS = ↑ HR and strength of contraction

Question 38

Q

What bpm would a denervated heart have?

Answer

A

~100bpm (=intrinsic heart rate)

Question 39

Q

What is a normal HR (bpm)? Which autonomic branch dominates?

Answer

A

Normal HR ~72bpm; dominated by PNS

Question 40

Q

By what percentage could SNS increase HR in theory?

Answer

A

SNS could in theory increase HR by 300%

Question 41

Q

By what percentage could PNS increase HR in theory?

Answer

A

By 100%, to 0bpm = cardiac arrest

Question 42

Q

What happens to autonomic innervation of the heart during exercise?

Answer

A

At onset of exercise, PNS activity decreases before sympathetic activity increases. = massive flexibility for HR to vary during different activities +increased SNS will increase contractility. ::Therefore enhanced SV from SNS contribution.

Question 43

Q

What are the following abbreviations? PWT SWT LVEDD

Answer

A

PWT=posterior wall thickness; SWT=septal wall thickness; LVEDD=Left ventricular end diastolic diameter

Question 44

Q

If left ventricular size increases, what also increases?

Answer

A

Stroke volume. eg. in athletes

Question 45

Q

What is the limiting factor to myocardial stretch?

Answer

A

The pericardium –Pericardectomy allows SV to increase and hence Q

Question 46

Q

What is the Frank-Starling law?

Answer

A

= the ability of the heart to change its force of contraction and therefore stroke volume in response to changes in venous return -aided by a health myocardium

Question 47

Q

↑ stretching of myocardial walls will ↑ strength of contraction… is part of what principle?

Answer

A

the Frank-Starling principle as stretching the ventricles increases the pressure they can generate

Question 48

Q

Does the heart ever stretch to the point of the ‘inaccessible region’ on a tension-sarcomere length graph?

Answer

A

No: There is no way to get a normal heart over the peak into the downslope of tension. The heart becomes very stiff above the optimal length, and the venous filling pressure never gets high enough.

Question 49

Q

What is a typical blood volume in adults?

Question 50

Q

What happens to blood flow distribution around the body during exercise?

Answer

A

Blood flow distribution is altered during exercise; cardiac output can increase 5x and skeletal muscle receives the majority at about 25,000mL. Blood is shunted away from non-essential organs.

Question 51

Q

How is blood flow distribution controlled?

Answer

A

via vasoconstriction (mediated by NE) and vasodilation (mediated by NO) NB: dilation>constriction

Question 52

Q

How does NO cause vasodilation?

Answer

A

It relaxes smooth muscle in response to increased shear stress

Question 53

Q

What are 7 things that cause vasodilation of arterioles?

Answer

A

bradykinin 2. prostaglandins 3. K+ 4. CO2 5. Lactate 6. local decrease in O2. 7. NO

Question 54

Q

What causes vasoconstriction?

Answer

A

NE, which acts on alpha receptors in smooth muscle to cause constriction

Question 55

Q

What percentage of blood resides in the venous system at rest?

Question 56

Q

How does exercise effect venous capitance?

Answer

A

With exercise need to return more to central circulation to increase venous return • ↑ SNS activity with exercise leads to venoconstriction

Question 57

Q

What percentage of blood shunting occurs through venoconstriction?

Question 58

Q

What is the main system that returns venous blood to the heart?

Answer

A

Muscular pump system in conjunction with venous valves.

Question 59

Q

What are the 5 methods that return blood to the heart?

Answer

A

Muscular pump system 2. Venoconstriction 3. Low pressure of ventricle during diastole (creates vacuum) 4. Ventricular rotation during systole and recoil during diastole sucks blood back into myocardium 5. The abdomino-thoracic pump: ↑respiratory pressure in thorax during respiration ↑blood return to heart

Question 60

Q

Increasing the rate and depth of inspiration would have what effect on the heart?

Answer

A

↑venous return and enhanced CO

Question 61

Q

What effect does the Valsalva manoeuvre have on venous return?

Answer

A

forced expiration against a closed glottis (Valsalva maneuver) impedes and therefore reduces venous return and cardiac output

Question 62

Q

What is afterload?

Answer

A

how much blood is left in the heart at the end of contraction (End systolic volume)

Question 63

Q

What 6 factors affect afterload?

Answer

A

Volume of blood in the arterial circulation 2. Pressure in aorta at onset of ejection (DAP) 3. Compliance of aorta 4. Inertial component of the ejecting blood column 5. Systemic vascular resistance 6. Size of pulmonary / aorta lumen

Question 64

Q

What are the 3 main effects of increased afterload?

Answer

A

Stroke volume will be reduced in the acute phase ::Preload will increase (which is a compensation mechanism to restore SV by Frank-Starling mechanism) 2. Reduced velocity of contraction and ejection in acute phase 3. Marked increase in myocardial O2 consumption

Answer 62

A

>200mmHg has direct impact on reducing cardiac output

Answer 63

A

Mechanoreceptors 2. Baroreceptors 3. Chemoreceptors 4. Metaboreceptors 5. Bainbridge reflex

Answer 64

A

Type III (lightly myelinated) afferent receptors a. Receptors that detect stretch and muscle contraction send afferent signals to brain to increase SNS activity

Answer 65

A

Type IV (unmyelinated) afferent receptors a. Sensitive to >lactate, phosphate, PGs,

Answer 66

A

a. In walls of carotid sinus and aortic arch b. Sense arterial pressure; are stretch activated c. Afferent nerves IX (carotid) and X (aortic arch) to brain d. Triggers brain to decrease SNS and increase PNS i. via increased peripheral dilation and reduced HR and Q :: reduced BP ii. = INHIBITION of vasometer and cardioacceleratory centres iii. = STIMULATION of cardio inhibitory centres

Answer 67

A

Afferent nerves IX (carotid) and X (aortic arch) to brain

Answer 68

A

It is the question of how the body gets round increased BP during exercise (which you would think leads to decreased HR?) i. The baroreflex is reset to a higher operating pressure with exercise ii. Won’t kick in until a higher arterial reassure is reached iii. Thus HR and Q can increase with exercise

Answer 69

A

a. In walls of carotid sinus and aortic arch – sense >SpCO2 b. Triggers brain to >SNS and HR

Answer 70

A

a. Increased cardiac filling elicits tachycardia b. ↑ right atrium filling from ↑ venous return c. Stretch receptors in right atria and vena cava stretched d. ↑ firing rate to brain e. Brain ↑ SNS tone f. ↑ HR and SV

Answer 71

A

a. Increased cardiac filling elicits tachycardia b. ↑ right atrium filling from ↑ venous return c. Stretch receptors in right atria and vena cava stretched d. ↑ firing rate to brain e. Brain ↑ SNS tone f. ↑ HR and SV

Answer 72

A

o Normal microvascular wear and tear o Fibrinogen o Free radicals o High blood pressure o Turbulent flow o Atherosclerotic lesions often occur at artery intersections or curves o Blood flow speed and direction changes creating turbulence o Viral attack o Carbon monoxide

Answer 73

A

• Classic symptoms: intense, oppressive chest pressure radiating to left arm • Other symptoms: chest heaviness, burning radiation to jaw, neck, shoulder, back, arms. nausea, vomiting dysponea. Lightheadedness. Sweating (cold and clammy). Confusion.

Answer 74

A

They are the result of absence of electrical activity. A myocardial infarction can be thought of as an elecrical ‘hole’ as scar tissue is electrically dead and therefore results in pathologic Q waves.

Answer 75

A

Released from damaged myocytes. Cardiac troponins I & T (initial rise 4-6h; peak 12-24h post-MI) CK (4-6i; 12-24 peak) CK-MB (4-6h initial; peak 12-36h) Myoglobin (2h post) LDH (8-12i; 48-72p)

Answer 76

A

Branching from the ascending aorta Left coronary artery -[Circumflex; Left anterior descending / AIB] Right Coronary artery [Marginal artery]

Answer 77

A

Left coronary artery Circumflex Right Coronary artery Posterior interventricular artery

Answer 78

A

Pressure in the muscle tissue during systole opposes blood flow. The effect is maximal in the deeper layers.

Answer 79

A

Tachycardia leads to decreased diastolic time. a. diastole decreases more than systole at ↑ heart rate 2. Low diastolic pressure 3. Ischaemic heart disease - large vessel or small vessel

Answer 80

A

↑ heart rate → ↑ coronary blood flow, by autoregulatory vasodilation – In ischaemic heart disease, ability to deliver ↑ flow is limited

Answer 81

A

70,000 (BHF, 2015) Biggest single killer CVD cost the country approx…. £15 billion

Answer 82

A

7 in 10 (BHF, 2015)

Answer 83

A

Pro-inflammatory M2 macrophages in the vascular smooth muscle bind and transduce signals from oxLDL and thus differ from those in adipose tissue or hepatic tissue. As these macrophages ingest oxLDL to become the lipid-rich foam cells characteristic of atherosclerosis, their molecular signature changes further. Foam cells differ markedly from normal resident macrophages in healthy vessels in that foam cells are less mobile and secrete more inflammatory mediators than normal macrophages

Answer 84

A

Foam cells are the fat-laden M2 macrophages seen in atherosclerosis. … Foam cells are formed when the body sends macrophages to the location of a fatty deposit on the blood vessel walls

Answer 85

A

o Arterial enlargement around area of the stenosis can keep lumen open even with large plaque

Answer 86

A

i. Atherosclerosis ii. Plaque rupture (Most likely in fatty plaques; Fibrous capped plaques more stable) iii. Platelet aggregation>Thrombus formation>Vessel occlusion iv. Vasospasm v. Distal ischaemia & Ischaemic complications

Answer 87

A

Endothelial damage 2. Stenosis 3. Formation of plaque

Answer 88

A

Virchow’s triad describes the three broad categories of factors that are thought to contribute to thrombosis. Hypercoagulability. Hemodynamic changes (stasis, turbulence) Endothelial injury/dysfunction.

Answer 89

A

o 85% of all infarct related lesions are in vessels that are less than 75% occluded o A fibrous cap makes the plaque more stable

Answer 90

A

left circumflex

Answer 91

A

Anterior LAD

Answer 92

A

Septum LAD

Answer 93

A

left lateral left circumflex

Answer 94

A

Inferior RCA

Answer 95

A

Transient (<30 minutes), episodic chest discomfort resulting from myocardial ischemia Predictable, reproducible Often follows physical exertion or emotional stress Pathophysiology: fixed, stable intra-coronary lesion– no thrombus!

Answer 96

A

ECG: normal, T-wave changes, or ST depression

Answer 97

A

Harbinger of myocardial infarction New-onset angina Rest angina Angina worsening in severity or occuring with less physical / emotional provocation Pathophysiology: atherosclerotic lesion +/- thrombus formation ECG: normal, T-wave changes, or ST depression

Answer 98

A

Ischaemia - generally associated with inverted T waves or S-T segment depression (disappears on rest in transient ischaemia) Injury - generally associated with S-T segment elevation and t-wave inversion Infarct - generally associated with Q waves

Answer 99

A

The ischaemic myocardium is slow to repolarise and remains more positively charged than the surrounding areas

Answer 100

A

Delayed depolarisation + tall T waves due to potassium leakage from dead cells

Answer 101

A

Proximal LAD = 25% 1-yr mortality Small inferior = 7%

Answer 102

A

With cell death • Holes develop in cell membrane • Contents leak dependent on size, solubility • Small, cytoplasmic markers leak quickly • Larger, complex markers released slowly • These markers are not released during ischaemia • Direct relationship between concentration of these markers and size of infarct

Answer 103

A

Anti-ischaemics (O2, B-blockers, Nitrates, morphine) 2. Anti-thrombotics (streptokinase, tpa, heparin) 3. Reperfusion (t-PA, PTCA, CABG)

Answer 104

A

In first 4-6h – acute ischemia Poor contraction, loses systolic power – floppy bag Infarct dilation and remolding – 7 days Inflammation bruising thinning of ventricular wall and enlargement of infarct site Necrosis during first 6-12 weeks May develop congestive heart failure Scarring Scar tissue leads to increased stiffness Partially resolves with time

Answer 105

A

Blood thinners (Aspirin / Heparin / Warfarin) - β-Blockers (Atenolol [Reduce heart work] - Calcium channel blockers (Diltiazem) [Decrease peripheral resistance = less heart work] - ACE inhibitors (Lisonopril) [Decrease peripheral resistance = reduces BP and less heart work + Aids fibrin dissolving] - Diuretics (Frusemide) [Reduce blood volume = reduces BP and heart work reduces] - Cholesterol lowering drugs (Statins)

Answer 106

A

Medical therapy + exercise stress test + cardiac rehab & GP (risk factors, medication, risk stratification)

Answer 107

A

Angiogram + CABG/PTCA + cardiac rehab + GP

Answer 108

A

Angiogram with or without PTCA (balloon angioplasty) o alternatives include laser angioplasty and atherectomy 2. CABG o Saphenous vein graph or left internal mammalian artery graph

Answer 109

A

Phase I: before discharge from hospital (assessment, advice, medication) Phase II: early post-discharge period (assessment + lifestyle advice) Phase III: As early post-discharge period plus (exercise sessions, access to trained support) Phase IV: long term maintenance of changed behaviour (1’ care follow up, local cardiac support groups, referral to specialists)

Answer 110

A

• 13–26 per cent reduction in all-cause mortality • 26–46 per cent reduction in cardiac mortality • 23–56 per cent reduction in hospital re-admission • Cost-effective • Improved quality of life • Improved functional capacity • Supports early return to work

Answer 111

A

CHD: National Service Framework 200 • NSF, published in March 2000 • Standard 12

Answer 112

A

VO2 = Q x (a-v)O2

Answer 113

A

50% lower than normal: 20 mL.kg-1.min-1 males 15 mL.kg-1.min-1 females

Answer 114

A

Inverse relationship

Answer 115

A

• Highest survival = pVO2 >18mL.kg-1.min-1 • Lowest survival = pVO2 <10mL.kg- 1.min-1 • Holds true for MI and Surgery patients

Answer 116

A

Each 1mL.kg-1.min-1increase in aerobic capacity reduces CV mortality risk by 10%

Answer 117

A

Each 1 MET increase in aerobic capacity reduces CV mortality risk by 15%

Answer 118

A

Due to lower CO/Q. Rest = SV (75 ml) x HR (60 bpm) = Q (4.5L.min-1)

Answer 119

A

Q drops & reduced maximal Q

Answer 120

A

↑ with exercise intensity • levels off after approx. 50% peak VO2 • Dictated by – Venous return (EDV = Preload) – TPR (ESV =afterload) – Myocardial contractility

Answer 121

A

• Stroke volume is reduced after approx 60% PVO2 • TPR is higher at all work levels than in healthy persons – Poorer sympathovagal regulation – blunted NO production • This increases afterload

Answer 122

A

• TPR is higher at all work levels than in healthy persons – Poorer sympathovagal regulation – blunted NO production • This increases afterload

Answer 123

A

• Higher submaximal exercise HR – ↓ SV – ↑ sympathetic activation • Lower peak HR

Answer 124

A

• Higher submaximal exercise HR – ↓ SV – ↑ sympathetic activation • Lower peak HR

Answer 125

A

They fail to increase HR so CO remains low. This is due to a blunted HR response: – Right coronary stenosis – ↓ sympathetic sensitivity

Answer 126

A

• Exercise may cause localised coronary vasoconstriction • This reduces blood supply to myocardium making it hypokinetic • Why? – Subnormal production of endothelial nitric oxide – Localised overproduction of endothelin

Answer 127

A

• ↓ submaximal and peak Q (SV x HR) – Major factor is ↓↓SV – ↑or↓HR Ultimately a lower SV will mean a reduced max Q

Answer 128

A

• body has excess blood needed for rest – two-thirds of blood resides in veins at rest • body has insufficient blood needed for maximal exercise – blood is shunted away from non-working and towards working muscles • Cardiac patients do not redistribute blood as effectively around the body – Visceral blood flow as % resting value • Normal = 20% • Cardiac = 50% • Therefore less delivered to the muscles

Answer 129

A

Lower peak VO2 Lower peak work rate Work at a higher % of maximum during submaximal exercise Lower VO2 during submaximal exercise Slower oxygen kinetics Greater reliance on anaerobic system to fuel the exercise

Answer 130

A

↑ Stroke volume – ↑ contractile function • ↑ calcium handling proteins in cell wall and SR – ↑ LV chamber volume (eccentric) • Myocyte elongation as sarcomeres added in series: occurs after 5 weeks – ↑ LV muscle mass (concentric) • More myocytes added in parallel (hypertrophy) – ↑ in plasma volume • 10% PV expansion may occur in just 10 days

Answer 131

A

T=(PR)/M • Where T is the tension in the walls • P is the pressure difference across the wall • R is the radius of the cylinder • M is the thickness of the wall To keep wall tension the same, the radius and the wall thickness must be proportional

Answer 132

A

HR Myocardial contractility Tension development

Answer 133

A

Wall thickness must increase or else wall tension increases.

Answer 134

A

Hormones & mechanical stress

Answer 135

A

Cortisol, growth hormone, thyroxine, renin, angiotensin, IGF, testosterone show acute ↑ with exercise (all potentially anabolic) 1. NE and epinephrine stimulation of alpha and beta receptors in the myocardium cause cardiac growth 2. RAAS – ↑ SNS activity reduces renal blood flow during exercise, ↑ renin release, thus ↑ RAA levels – ↑ RAA levels stimulate cardiac myocytes to hypertrophy 3. GH and IGF – Cardiac myocytes have receptors for both GH and IGF – Stretching of heart muscle is trigger for these hormones to activate gene expression – IGF increases myofilament sensitivity to Ca++ thus ↑ contractile force 4. Thyroid hormones – Exercise stimulates TSH, thus thyroxin production – Thyroxin causes myocyte hypertrophy

Answer 136

A

• Pressure overload = ↑ resistance = hypertrophy through ↑ cross sectional area (Concentric) • ↑ volume overload = hypertrophy through ↑ myocyte lengthening (Eccentric) • Mechano-sensors in myocyte activated by stress: – Surface receptors (integrins) and stretch activated ion channels ↑ CA++ influx → activate protein kinase pathways → hypertrophy

Answer 137

A

Improved contractility & Angiogenesis Improved contractility • Improved % shortening, time to peak shortening, relaxation time – ↑ calcium binding sites in myocytes – ↑ Na+ - Ca++ exchanger pumps speed removal of Ca back into SR – ↑ Ca stored in SR = more Ca = more contractile force – ↑ Ca sensitivity of myofilaments • Increased ATPase expression • Angiogensis – Myocyte hypertrophy comes with angiogensis to increase blood flow • Increased arterial size to be equal or greater than increase in cardiac mass (over adaptation!) • Increased capillarisation

Answer 138

A

states that wall tension (T) is proportionate to the pressure (P) times radius (r) for thin-walled spheres or cylinders

Answer 139

A

Due to La Place’s law: if pressure in the myocardium is raised due to HTN, and left ventricle volume overload is caused by exercise, concentric and eccentric hypertrophy develop in response.

Answer 140

A

Pressure overload = ↑ resistance = hypertrophy through ↑ cross sectional area (Concentric) • ↑ volume overload = hypertrophy through ↑ myocyte lengthening (Eccentric)

Answer 141

A

Pressure overload = ↑ resistance = hypertrophy through ↑ cross sectional area (Concentric) • ↑ volume overload = hypertrophy through ↑ myocyte lengthening (Eccentric)

Answer 142

A

Surface receptors (integrins) and stretch activated ion channels ↑ CA++ influx → activate protein kinase pathways → hypertrophy

Answer 143

A

LV hypertrophy may occur through chronic overload due to high BP (afterload stressor) and through a greater preload as heart stays full of blood • This hypertrophy is not good because: – Preload / afterload engorgement and increased resistance to arterial flow causes hypertrophy in both series and parallel of myocytes to compensate – Reduced contractile function • No increase in SR Ca pumps – Reduced SR uptake of Ca lengthens relaxation time – Reduced Ca reservoir for contraction initiation – No increase in Ca sensitivity by myofilaments

Answer 144

A

↑ Stroke volume 0 - 18% – ↑ blood volume 6-10% – Myocardial hypertrophy – Improved contractile force - ↓ ESV – ↑ ejection fraction – ↑ Heart rate variability

Answer 145

A

• Partial regression of vascular stenosis (>2200kcal/wk)

Answer 146

A

increased SV - decreased blood viscosity (reduced fibrinogen) - angiogenesis of coronary collaterals - Partial regression of vascular stenosis (>2200kcal/wk) - Increase in cardiac capillary blood flow - Reduced endothelial dysfunction - exercise training may reduce myocyte length to normal (aids contractile fx)

Answer 147

A

No, the reverse. Their hearts are already hypertrophied due to the stress they are under; Paradoxically exercise training may reduce myocyte length to “normal”, but this helps contractile function • Contractile function – Normal length myocytes contract better – Improvements occur due to same reasons as for healthy people

Answer 148

A

• Small ↓ in resting HR • Resting Q remains the same

Answer 149

A

• ↑inmaxSV • ↓ In sub-maximal exercise heart rate - but this may arise without increase in SV • ↓ Systolic blood pressure response – ↑ Nitric oxide production, ↑ vasodilation thus ↓ TPR • ↓ In myocardial oxygen demand (measured by RPP) • Small ↓ in Submax exercise Q • Improvement in max cardiac output • ↑ Arteriovenous difference - more O2 extracted

Answer 150

A

↑ Arteriovenous difference - V. important as may cause ↑ in peak VO2 without ↑ in Q. ↑ Mitochondrial number and quantity of aerobic enzymes Shift towards a more aerobic muscle fibre type profile ↓ submaximal exercise muscle blood flow because of ↑ usage of delivered O2 ↑ Maximal muscle blood flow ↑ Muscle capillary density ↑ Muscle fibre recruitment ↓ Blood lactate concentration during sub-maximal exercise

Answer 151

A

Wasserman & Whipp (1975); Sullivan et al (1991)

Answer 152

A

↑PeakVO2 10 to 50% with mean @ 20%

Answer 153

A

• ↑ Total exercise capacity (exercise time and / or distance): 18-35%

Answer 154

A

• ↑Angina threshold: 10- 20%

Answer 155

A

Looked at all cause mortality in CAD patients with change in EE. All cause mortality greater in people whose EE level had decreased • Irrespective of age or sex • Mortality risk 24% higher if EE ↓ by 1000Kcal.wk, but 19% lower if EE ↑ by 1000 Kcal.wk

Answer 156

A

Mortality risk 24% higher if EE ↓ by 1000Kcal.wk but 19% lower if EE ↑ by 1000 Kcal.wk

Answer 157

A

70-80% If MVO2 ↑ during exercise ⇒ little scope to ↑ extraction ⇒ must ↑ coronary blood flow

Answer 158

A

When myocardial oxygen (either blood flow or oxygen extraction) cannot meet demands.

Answer 159

A

Rate pressure product is used in cardiology and exercise physiology to determine the myocardial workload RPP = SBP X HR Max exercise RPP >25,000mmHg.bt.min

Answer 160

A

Submax exercise ↓SBP(froma↓inQ and TPR) ↓ HR ↑ in angina threshold

Answer 161

A

* Self Care Activities * Arm and leg range of motion movement * Low Resistance activities * Minimal activities - active remodelling of myocardium occurring. Don’t want to exacerbate damaged area.

Answer 162

A

Walking. 1 1/4 mile 4 days / week 2 1/2 mile 4 days / week 3 3/4 mile 4-5 days / week 4 3/4 mile 4-5 days / week 5 1 mile 5 days / week 6 1 mile 5 days / week • Walk at a comfortable pace (RHR + 20bpm) • Take GTN spray • Know rules of chest pain • Choose flat route • Go with someone at first • Once solo, let others know the route

Answer 163

A

– Clinical maximum – Peak HR, VO2 – Exercise capacity – Angina threshold

Answer 164

A

16 2. 23 3. 34 4. 46 5. 57 6. 68

Answer 165

A

• Reaching estimated max HR ± 10bts.min-1 • Light headedness, confusion, ataxia, cyanosis, dysponea, nausea • Onset of angina • Symptomatic SVT • ST depression >2mm • VT • Exercise induced LBBB Why • Onset of 2nd or 3rd degree heart block • One R on T PVC • PVC’s accounting for >30% of all complexes • Hypotension (>20mmHg drop in BP) • Hypertension (>220 mmHg SBP : >110mmHg DBP) • Inappropriate bradycardia (drop in HR >10 beats / min) with increase or no change in work load

Answer 166

A

Determine peak HR from test data [The highest HR achieved before problems (Angina etc)] Calculate training heart rate zone: 40-80% of the peak HR value recommended – some studies suggest 70-85% as intensity threshold – Use common sense

Answer 167

A

1 MET =resting oxygen uptake (3-4mL.kg- 1.min-1)

Answer 168

A

3-4 (stage 1 etc) 5-7 7-9 9-11 11-13

Answer 169

A

W: 3 - 10 METS C: 3 - 8 METS D: 4 - 8 METS G: 4 - 7 METS J: 8 - 16 METS F: 5 - 12 METS T: 4 - 9 METS S: 4 - 8 METS

Answer 170

A

(HRR = predicted max HR - resting HR) + resting HR

Answer 171

A

(6 x (200-60)) + 60 = 84 + 60 = 144 bts.min-1 (HRR = predicted max HR - resting HR) + resting HR

Answer 172

A

β-blocked = 203-1.49(age) Non β-blocked = 252-1.91(age) Brodie et al., (1998)

Answer 173

A

12-16 (fairly light-upper hard limit)

Answer 174

A

Regular training (3d.wk-1) for minimum of 3 months needed for significant changes to be seen

Answer 175

A

You could use peak HR, or HRR, or METS, or RPE!

Answer 176

A

• Long warm up period of at least 10 minutes • A mixture of aerobic exercise and resistance exercise can be used • Exercise intensity should be set at an intensity of 50-80% of peak HR, 50-70% HRR, 12-16 / 4-6 RPE, or 5-8 METS. • Intermittent exercise (work / rest) is often better tolerated • Start with 10-15 minutes total exercise time, increasing to 30-60 minutes • Exercise all major muscle groups - at least 10min cool down

Answer 177

A

6 week post-surgery. Make sure leg and sternal wounds are well healed. • Warm up • Commence with a programme of aerobic exercise • Flexibility exercises for the pectorals, shoulder and legs • Exercise intensity should be set at an intensity of 50-80% of HRR, 12-16 / 4-6 RPE, or 5-8 METS. • Start with 10-15 minutes total exercise time, increasing to 30-60 minutes • Upper body resistance exercises should be included with patient agreement, but under close supervision - cool down

Answer 178

A

– Better tolerated by patients – accumulation of exercise allows a greater total amount of work to be performed per session – Rest allows HR and SBP to ↓, thus MVO2

Answer 179

A

• Work periods ∝ 2-3 minutes • May start with 5 reps of 30 seconds • 1:1 work:rest ratio • Supine & upright exercises not interspersed – ↑ preload = ↑ MVO2 – Orthostatic hypotension

Answer 180

A

• Ask the person!!! • 10% every 2 weeks • Durationthenintensity • Don’t be afraid to↓ work load

Answer 181

A

• Walkingspeedshould achieve HR in training zone • Pleasurable

Answer 182

A

• METS 4-7 • Aerobic/anaerobic • Flatcourse • 9 Holes at first,↑ number slowly • 3/4swing • Half set of clubs • Pull or carry clubs • Chest pain rules

Answer 183

A

• Bowls has NO cardiovascular benefit • But will improve co- ordination, flexibility and confidence in physical activity

Answer 184

A

• No swimming until sure of arrhythmia / angina / wound status • METS4-8 • Is HR in training zone? • Vary stroke • Chest pain rules • Cold water

Answer 185

A

• Congestive Heart Failure • Severe Valvular Disease • Low ejection fractions • Uncontrolled Arrhythmias • Significant left ventricular dysfunction

Answer 186

A

Safe CV responses seen if load is < 60%1RM Keep RPP below trigger point • Can exercise > 5 MET • Circuits of 6-10 exercises • 8-20 repetitions • 2-3 d.wk-1 • Light weight (30-80% 1RM) • Alternate arm / legs • Alternate arms or legs • Controlled breathing • Sitting or standing (Ehrman, 2013)

Answer 187

A

Similar (i.e. increase in SBP and HR)

Answer 188

A

• Muscle develops tension but does not shorten • Note how both SBP and DBP increase

Answer 189

A

• Muscle develops tension but does not shorten • Note how both SBP and DBP increase

Answer 190

A

> intra muscular pressure BP >>TPR >intrathoracic pressure

Answer 191

A

– ↑ BP ⇒ ↑ RPP (HR X SBP∴MVO2) not problematic if < 80% 1RM – ↑ HR; 60-80% HR max during circuit weights – ↑ VO2; 30-50% VO2max during circuit weights

Answer 192

A

Type (isotonic / isometric) Weight lifted (% 1RM) Duration of rest intervals Starting CV fitness of person Medications

Answer 193

A

Muscular strength: ↑ 20-30% in cardiac patients ↑ efficiency of movement Small ↑ in peak VO2 Improved blood lipid profile ? Improvement in body composition ?

Answer 194

A

20-30% increase

Answer 195

A

4-6weeks into supervised cardiorespiratory endurance exercise program • Use elastic bands, light handweights, or resistive tubing to add variety • Monitor heart rate and ECG continually • >? Ask the person !!! • 10 % every 2 weeks • > Reps then intensity • Don’t be afraid to ↓ work load

Answer 196

A

Buoyancy, water resistance and temperature ↓ joint compression forces Stimulus for muscular development Useful for people with orthopaedic limitations Weight management due to greater EE

Answer 197

A

Hydrostatic pressure forces blood back into the central circulation ↑ venous return ↑ heart blood volume 200ml ↑ SV 30-50% HR same or ↓ ↑ Q 25% ↑ Mean BP 12mmHg - vasoconstriction in cold water, dilation in warm Diuretic effect - dehydration, ↓ blood volume

Answer 198

A

↑ incidence of Ventricular arrythmias (esp Ventricular ectopic beats) ↑ ST depression But why? Unclear Breath holding = ↑ SNS tone to heart especially after taking a breath prior to holding∴ more arrhythmia risk This is different from the breath hold dive reflex which works after facial immersion in cold water (<20°C) which causes bradycardia No increase in angina

Answer 199

A

Hydrostatic pressure squeezes the thoracic cavity • ↓vitalcapacity5-10% • ↓gasexchange • ↓PaO2 • ↑loadonrespiratory muscles

Answer 200

A

– CHD patients work at higher % of maximum (50-80%) – Yet RPE similar between groups - feels easier than it is, safety issue!

Answer 201

A

TM>CE>W for both CHD and healthy people

Answer 202

A

Should be restricted to low risk patients - 10 beats off training HR to be safe Limited evidence as yet

Answer 203

A

All health adults: >150min MPA/ 75min VPA/ equivalent mix (aerobic) + weight training/ resistance (8-10 exercises) 2d/week at a weight that brings muscle fatigue after 8-10 reps Beginners: work steadily towards meeting the PA levels recommended Conditioned individuals: meeting recommendations for >6months may gain additional benefits by 300min MPA/ 150min VPA/ week

Answer 204

A

5-16y: at least 60min MVPA per day, including VPA activities that improve bone density and muscle strength

Answer 205

A

To go beyond the recommended ‘healthy’ adult levels and progress towards conditioned individual recommendations. (300min MPA/ 150min VPA)

Answer 206

A

Reduce sedentary time, reduce energy intake, + 300min MPA/ 150min VPA

Answer 207

A

A large volume of resistance training may lead to overreaching and overtraining if the balance between training and recovery is inappropriate [over- reaching refers to a decrease in performance that may last several days to several weeks and overtraining refers to a decrease in performance that may last several weeks to several months and may be accompanied by greater fatigue, performance decline, and mood disturbance (Halson & Jeukendrup, 2004)].

Answer 208

A

The reductions in morbidity and mortality associated with physical activity might sound modest, but they are the most conservative of estimates obtained by statistically isolating physical activity from potential confounders, such as age, smoking habit, cholesterol profile, and blood pressure. (Mora, Cook, Buring, Ridker, & Lee, 2007). 2. It is also possible that the relationship between physical activity (exposure) and health (outcome) has been underestimated because it has been difficult to measure accurately people’s exposure to physical activity (Lee & Paffenbarger, 1996)

Answer 209

A

Obesity, depression, hypertension, diabetes, hyperlipidaemia.

Answer 210

A

Although more research is required, there is some evidence that bouts of less than 10 min may also be beneficial to health (Miyashita, Burns, & Stensel, 2008; Strath et al., 2008). There is also growing evidence that it is beneficial to avoid sitting and other sedentary behaviours (Hamilton, Hamilton, & Zderic, 2007; Levine, 2007).

Answer 211

A

Although more research is required, there is some evidence that bouts of less than 10 min may also be beneficial to health (Miyashita, Burns, & Stensel, 2008; Strath et al., 2008). There is also growing evidence that it is beneficial to avoid sitting and other sedentary behaviours (Hamilton, Hamilton, & Zderic, 2007; Levine, 2007).

Answer 212

A

Moderate: 4-6 METs Vigorous: >6 METs

Answer 213

A

• Walking for transport • Public spaces for recreation • Neighbourhood design • Safety of routes for school commutes

Answer 214

A

Chlamydia pneumonia Herpes family viruses Cytomegalovirus

Answer 215

A

Cyclosporine + sirolimus (immunosuppressive drugs) block the activation of T cells, inhibit intimal lesions and at high doses inhibit smooth muscle proliferation. COX-2 inhibitors eg. Rofecoxib Lipid-lowering statins Vaccination

Answer 216

A

26-33oC Public pools about 29C

Answer 217

A

Hot: vasodilation; vasovagal syncope Cold: arrhythmias

Answer 218

A

Gradually increase time up to 10 mins. Drink plenty of water. NEVER use the plunge pool before/afterwards.

Answer 219

A

6 weeks after MI to allow myocardial tissue to recover 12 weeks after CABG to allow sternal healing

Answer 220

A

• If your device has recently been put in you should wait at least six weeks to allow the wires to settle • You are advised only to use breaststroke. Front crawl, backstroke and fly can potentially damage the leads due to repeated strain on them • With an ICD you should always have someone with you or be in a lifeguard supervised pool, in case the device activates and you need help