Concepts/Hemodynamics Flashcards

Question 1

Q

Cardiac output definition

Answer

A

amount of blood ejected by the LV in 1 minute.

Question 2

Q

CO may be determined by what test

Answer

A

cardiac catheterization

Question 3

Q

CO formula

Question 4

Q

Normal CO =

Answer

A

4-8 L/min

Question 5

Q

3 factors affecting cardiac output

Answer

A

Changes in HR
Changes in contractility
Changes in venous return

Question 6

Q

How does excessive High HR affects cardiac output?

Answer

A

excessively high HR, ↓diastolic filling time thus ↓ CO

Question 7

Q

Changes in contractility affect CO how?

Answer

A

↑ Sympathetic activity causes ↑ myocardial contractility (positive inotropy) and thus more blood is ejected (↑ SV); this ↑ CO

Question 8

Q

What change in preload affect CO?

Answer

A

↑ preload, ↑ force of contraction thus ↑ CO

Question 9

Q

Changes in resistance increase or decrease will affect

Answer

A

SV and CO

Question 10

Q

High afterload effect on SV and CO

Answer

A

= ↓ SV and ↓ CO

Question 11

Q

Changes in venous return

Answer

A

↓ blood volume, ↓ venous return, ↓ preload = ↓ SV and ↓ CO

Question 12

Q

Venous constriction effect on venous return, SV, and CO

Answer

A

= ↑ venous return to the heart, ↑ preload,

↑ SV, ↑CO

Question 13

Q

Cardiac index is the

Answer

A

CO corrected for differences in body size.

Question 14

Q

CI is based on

Answer

A

It is based on body surface area (BSA)

Question 15

Q

CI formula is

Answer

A

CI = CO/BSA

Question 16

Q

Normal CI =

Answer

A

2.5 - 4L/min

Question 17

Q

2 things that increase CI

Answer

A

Exercise

Mild tachydysrhythmias

Question 18

Q

2 things that my decrease CI

Answer

A

Decrease myocardiac contractility, MI, CHF, cardiomyopathy and electrolyte imbalance

Question 19

Q

Increase afterload ______CI

Question 20

Q

Things that can increase afterload

Answer

A

Valvular stenosis and pulmonary HTN

Question 21

Q

Changes in preload that can decrease CI

Answer

A

Hypovolemia

Question 22

Q

How does tachy and irregular rhythm decrease CI

Answer

A

↓ diastolic filling time and causes loss of atrial kick.

Question 23

Q

What is Stroke Volume (SV)?

Answer

A

SV is the amount of blood ejected by the ventricle with each contraction; the difference between end-diastolic volume and end-systolic volume

Question 24

Q

SV formula

Question 25

Q

What is ejection fraction?

Answer

A

The percent of how much blood is pushed out of the left ventricle during contraction verses how much was there prior to contraction

Question 26

Q

Normal EF is

Answer

A

greater than 50 % but usually 60-75%

Question 27

Q

Preload is the___? What is it determined by ?

Answer

A

stretch on the myofibrils at the end of diastole; determined by the pressure in the ventricle at the end of diastole.

Question 28

Q

The pressure or volume in the ventricles at the end of diastole.

Question 29

Q

↑ preload is accomplished by

Answer

A

↑ volume return to the ventricles

Question 30

Q

Evaluation of preload: What evaluated RV preload?

Answer

A

RV preload = CVP or RAP (Right Atrial Pressure)

Note as preload ↑, myocardial oxygen demand/consumption ↑

Question 31

Q

What evaluates LV preload?

Answer

A

o LV preload = PAOP or LAP (Left Atrial Pressure)

Question 32

Q

Mitral valve stenosis on preload

Question 33

Q

Mitral insufficiency on preload

Question 34

Q

Aortic insufficiency on preload

Question 35

Q

Increase blood volume on preload

Question 36

Q

Decrease blood volume on preload

Question 37

Q

Vasodilators on preload

Question 38

Q

Vasoconstrictors on preload

Question 39

Q

Afterload is the pressure

Answer

A

against which the ventricle must pump to open the

semilunar valve.

Question 40

Q

Vascular resistance:
o RV afterload =
o LV afterload =

Answer

A

oPVR (Pulmonary Vascular Resistance)
oSVR (Systemic Vascular Resistance)
o Ventricular diameter
o Mass and viscosity of blood

Question 41

Q

Mass and viscosity of blood affect

Answer

A

Vascular resistance

Question 42

Q

As afterload increase, what happens to myocardial oxygen demand/consumption

Question 43

Q

Aortic valvular stenosis effect on afterload

Question 44

Q

Aortic valvular stenosis effect on afterload

Answer

A

Peripheral arterial vasonstriction

Question 45

Q

Hypertension effect on afterload

Question 46

Q

How does polycythemia affect afterload?

Question 47

Q

Drug that ↓ afterload

Answer

A

Hydralazine

Question 48

Q

Drugs that ↑ afterload:

Answer

A

LED
Levophed
Epinephrine
Dopamine

Question 49

Q

What is the intrinsic rate of a transplanted heart? i.e. non-innervated = no vagus nerve innervation.

Answer

A

120-130 BPM

Question 50

Q

What does Frank Starling’s Law mean?

Answer

A

Starling‟s Law states that the greater the stretch of the cardiac muscle, the more forceful the heart‟s contraction and beat.

Question 51

Q

Frank Starling’s Law limitation, When the muscle is overstretched, the force of contraction may

Answer

A

decrease below normal levels, causing circulatory failure.a rubber band breaking when stretched too far, rendering it useless.

Question 52

Q

Nicotinic receptors are located on

Answer

A

Located on the motor endplate

Question 53

Q

o All neuromuscular blocking agents work here.

Answer

A

Nicotinic receptors.

Question 54

Q

Pulsus paradoxus what is it? How do you treat it? What is in an indication of?

Answer

A

Pulsus paradoxus is an exaggeration of normal physiologic response to inspiration.

Question 55

Q

Pulsus paradoxus normal BP vs BP with inspiration

Answer

A

The normal ↓ BP during inspiration 10 mm Hg or less; therefore a BP ↓ > 10 mm HG during inspiration is pulsus paradoxus.

Question 56

Q

What are three things that PULSUS PARADOXUS INDICATES? Cardiac wise

Answer

A

Pericardial effusion
Constrictive pericarditis
Cardiac tamponade
Advance cardiogenic shock

Question 57

Q

What are three things that PULSUS PARADOXUS INDICATES? other than cardiac

Answer

A

Severe lug disease
advanced heart shock
hemorrhagic shock

Question 58

Q

Main treatment of cardiac tamponade

Answer

A

The main cause is cardiac tamponade and the treatment would be pericardiocentesis.

Question 59

Q

There is a patient having a laminectomy (bloody surgery). The orthopedic physician wants the patient to be hypotensive in order to decrease blood loss. An
ABG is drawn after the case has been going on for 4 hours. The patient is in metabolic acidosis. Why? and what solution (2 possible) ? if the physician ignore and wants pt hypotensive?

Answer

A

The increase blood loss leads to ↓ oxygen carrying capacity
Patient is hypotensive, ↓ peripheral perfusion
This ↓ in O2 capacity and ↓ perfusion causes the body to stop aerobic metabolism and switch to anaerobic metabolism
The byproduct of anaerobic metabolism is LACTIC ACID>.
Return the patient to a normotensive state by giving IVF and blood in order to correct the acidosis.
2. If # 1 does not work, then give NaHCO3
- You must stop the case, because if the patient stays acidotic and hypotensive they will expire.

Question 60

Q

Parasympathetic Nervous System

Cholinergic: dominant when?

Answer

A

Calm situations

Question 61

Q

Sympathetic Nervous System

Cholinergic: dominant when?

Answer

A

Crisis situations

Question 62

Q

Promotes activities that restore the body’s energy and resources

Answer

A

Cholinergic

Question 63

Q

Promotes activities that prepare the body

for crisis situations

Answer

A

Sympathetic nervous system

Question 64

Q

Eyes with parasympathetic

Answer

A

Constrict

Answer 50

A

↓ Rate, ↓ contractility

Answer 51

A

Heart: ↑ Rate, ↑ contractility

Answer 52

A

bronchoconstriction

Answer 53

A

Bronchodilation

Answer 54

A

Glycogenesis

Answer 55

A

Glycogenolysis, Lipolysis

Answer 56

A

↑ secretion ↑Salivary flow, ↑ Motility,

Answer 57

A

↓Salivary flow, ↓ Motility, ↓secretion

Answer 58

A

Bladder contracted

Answer 59

A

Sphincter open

Answer 60

A

Bladder relaxed

Answer 61

A

Sphincter closed.

Answer 62

A

No effect

Answer 63

A

Secretes epinephrine and norepinephrine

Answer 64

A

o A delay in passage of impulse from the atria to the ventricles.

Answer 65

A

usually unnecessary when it is asymptomatic

Answer 66

A

Some impulses are conducted and others are not.

Answer 67

A

Type I Wenckebach

Type II Mobitz

Answer 68

A

Usually occurs at the level of the AV node and is often due to increased parasympathetic tone or to drug effect (digitalis, propranolol, verapamil). It is

Answer 69

A

characterized by a progressive prolongation of the PR interval until an impulse is completely blocked.

Answer 70

A

o Treatment is rarely needed unless severe S/S are present. Priority given to identifying cause.

Answer 71

A

below the level of the AV node either at the

bundle of HIS or bundle branches.

Answer 72

A

PR interval does not lengthen before a dropped beat

Answer 73

A

It is usually associated with an organic lesion in the conductive pathway and thus associated with a poorer prognosis and a complete heart block may develop.

Answer 74

A

Atropine 1 mg rapid IVP: for symptomatic bradycardia
Transcutaneous / Transvenous pacemaker
Catecholamine infusions: Dopamine, Epi, Levophed
Permanent pacemaker.

Answer 75

A

Complete absence of conduction between the atria and the ventricles.

Answer 76

A

Atropine 1 mg rapid IVP: for symptomatic bradycardia
Transcutaneous / Transvenous pacemaker
Catecholamine infusions: Dopamine, Epi, Levophed
Permanent pacemaker

Answer 77

A

increased parasympathetic tone associated with inferior infarction, toxic drug effects (digitalis, propranolol) or damage to the AV node

Answer 78

A

Infranodal conduction disease. May also be due to coronary atherosclerosis, which is usually associated with an extensive anterior MI.

Answer 79

A

CHF is a state in which there is impaired cardiac function such that the ventricle is unable to maintain a CO sufficient to meet the metabolic needs of the body.

Answer 80

A

The LV, RV, or both fail.

Answer 81

A

Left sided heart failure
↓ CO, ↑ LV pressure and volume. -LV can‟t pump blood returning from the lungs…
o LA unable to empty into LV thus ↑ LA pressures.
o LA pressure reflected back to lungs producing pulmonary congestion.

Answer 82

A

Pulmonary pressure causes fluid to leak = pulmonary edema.
Oxygenation of blood as O2/CO2 exchange is impeded.

Answer 83

A

↑ pressure to the right side of heart.
o Right heart can‟t pump to lungs due to ↑ pressure in the pulmonary vasculature.
o Venous return impeded as right side of heart fails
o As Pressure builds, body organs become congested with venous blood.

Answer 84

A

RV infarcts.

Answer 85

A

Acute LV MI
Cardiomyopathy
Atherosclerotic heart disease
↑ circulating volume
Aortic stenosis/insufficiency
Cardiac tamponade
Mitral stenosis/ insufficiency
Tachy/Bradycardia

Answer 86

A

Left-sided heart failure
Atherosclerotic heart disease
Acute RV MI
Tachy/Bradycardia
Pulmonary embolism
Fluid overload
Excess sodium intake
Mitral stenosis
Atrial or ventricular septal defect
Pulmonary outflow stenosis
COPD
Pulmonary hypertension
Cor Pulmonale

Answer 87

A

Lung pathology

Answer 88

A

Chest discomfort, SOB, orthopnea, paroxysmal nocturnal dyspnea, weight gain, ↓ urination, edema

Answer 89

A

Right Depend E JAH
Dependent edema
JVD
Ascites
Hepatomegaly

Answer 90

A

Orthopnea
Cyanosis
Hypoxia
Dyspnea
More systemic signs

Answer 91

A

Cardiac glycosides and AMRINONE

Answer 92

A

↑ cardiac contractility without ↑ rate by ↑ cellular levels of cyclic AMP

Answer 93

A

Relaxes vascular smooth muscle producing peripheral vasodilation (↓ preload and ↓ afterload

Answer 94

A

Initial bolus 0.75-1.5 mcg/kg over 2-3 min followed by infusion 5-10 mcg/kg/min.

Answer 95

A

improve LV function by lowering systemic vascular resistance: ↓ afterload
o Nitroglycerin
o Nitroprusside

Answer 96

A

Glucose, insulin and NaHCO3:

Answer 97

A

temporarily drive K+ into cell

Answer 98

A

Because the cells are trying to compensate for the acidic environment by exchanging K+ out of the cell and H+ into the cell

Answer 99

A

cardiac contractility: contraindicated in patients on digoxin

Answer 100

A

Follow up with Kayexalate and sorbitol or HD for permanent removal

Answer 101

A

a state of transient myocardial ischemia without cell death

Answer 102

A

obstruction of circulation to a part. Ischemia leads to anaerobic metabolism and accumulation of lactic acid, causing chest pain

Answer 103

A

used to ↑ CO by ↑ HR, resulting in an ↑ in cerebral and coronary blood flow and an ↑ in SVR

Answer 104

A

Epinephrine

Answer 105

A

1 mg IV push Q 3-5 minutes.

Answer 106

A

↑ CO, ↑PAOP, ↑SVR, ↑MAP, ↑HR, ↑CVP, ↑PVR

Answer 107

A

1 - 4 mcg/min

Answer 108

A

It is used to ↑ low BP refractory to fluid therapy, to treat heart failure, increase renal perfusion, and correct hemodynamic imbalance in shock syndrome.

Answer 109

A

5 minutes, duration 10 minutes.

Answer 110

A

Low dose (renal perfusion) + 1-3 mcg/kg/min

Answer 111

A

(↑ contractility) = 3-10 mcg/kg/min. (Vasoconstriction) > 10 mcg/kg/min.

Answer 112

A

May induce myocardial ischemia. Nausea and vomiting especially at high doses

Answer 113

A

o The presence of ↑ vascular resistance, pulmonary congestion, or ↑ preload is a relative contraindication to the use of dopamine

Answer 114

A

o Renal ischemia at high doses.

o Tissue sloughing if IV infiltrates

Answer 115

A

> 20 mcg/kg/min

Answer 116

A

Synthetic sympathomimetic catecholamine with inotropic, chronotropic and vasodilator effects.

Answer 117

A

It stimulates β1 and α1 receptors.

Answer 118

A

Useful in treating heart failure (especially with ↑ SVR and PVR), to increase contractility with no significant increase in heart rate.

Answer 119

A

It is similar to dopamine but does not cause a significant rise in BP.

Answer 120

A

↑ CO, ↓ PAOP, ↓ SVR, ↑ MAP, ↑ HR (slowly), ↓ CVP, ↓P

Answer 121

A

Infuse at 2-10 mcg/kg/min. May go up to 40 mcg/kg/min. with MD approval.

Answer 122

A

Dobutamine

Answer 123

A

HA, nausea, tremor and ↓ K+

Answer 124

A

An anticholinergic parasympathetic. (Muscarinic receptors) It ↑ CO and ↑ HR by blocking cardiac vagal stimulation in the heart.

Answer 125

A

Used in bradycardia and bradydysrhythmias, blocking cardiac vagal reflexes (also to ↓ secretions and broncodilitation)

Answer 126

A

IV: give 1 mg q 3-5 minutes, not to exceed 3 mg.

Give rapid IVP as pushing slowly may cause paradoxical bradycardia lasting 2 minutes.

Answer 127

A

Narcotic analgesis

Answer 128

A

It relieves pulmonary congestion, lowers myocardial O2 consumption, and reduces anxiety.

Answer 129

A

Dilates veins and ↓ preload.

Answer 130

A

Side effects include respiratory depression, hypotension, ↑ ICP, N/V.

Answer 131

A

A venous and arterial dilator used to ↑ CO by ↓ LV afterload, to ↓ blood pressure in hypertensive crisis, and to ↓ pulmonary hypertension

Answer 132

A

↑ CO, ↓ PAOP, ↓ SVR, ↓ MAP, ↑ HR, ↓ CVP, ↓ PVR Infuse

Answer 133

A

0.5 – 10 mcg/kg/min.

Answer 134

A

Check thiocyanate level if infusion continues longer than 72 hour or if rate ≥ 4 mcg/kg/min.

Answer 135

A

Almond breath Antidote: Amyl nitrate inhaled, NA thiosulfate IV.

Answer 136

A

A venous vasodilator used to ↓ preload and afterload in LV failure. It is also used for myocardial ischemia and as a dilator for coronary vasculature.

Answer 137

A

There is no optimum fixed dose. Titrate to response. Most patients respond to 50 – 200 mcg/min.

Answer 138

A

Precautions: When piggybacking, do so close to the insertion site as tubing can absorb 40% -80% of drug.

Answer 139

A

Solution stable only 24 hours

Patients develop tolerance over 1-2 days.

Answer 140

A

Hyponatremia is when an excess of water relative to the amount of sodium in the body produces a dilutional effect on sodium concentrations.

Answer 141

A

Sodium < 136

Answer 142

A

condition characterized by impaired renal excretion of water, resulting in oliguria, high urine specific gravity, water intoxication and hyponatremia.

Answer 143

A

Sodium depletion
Diuretics
 Diarrhea
 Nasogastric suction
 Abnormal losses via diaphoresis
 Salt-losing renal diseases: interstitial nephritis
 Hyperglycemia (glucose induced diuresis)

Answer 144

A

Sodium depletion
Diuretics
Diarrhea
Nasogastric suction
Abnormal losses via diaphoresis
Salt-losing renal diseases: interstitial nephritis
Hyperglycemia (glucose induced diuresis)

Answer 145

A

o Kidneys may retain larger amounts of water in excess of sodium

Answer 146

A

0-15 mmHg

Answer 147

A

CPP = MAP – ICP

Answer 148

A

This represents the pressure gradient driving cerebral blood flow (CBF) and hence oxygen and metabolite delivery

Answer 149

A

o Normal 70-100 mmHg

Answer 150

A

Inferior, Superior (Common) Vena cava
↓
Right Atrium
↓
Tricuspid Valve
↓
Right Ventricle
↓
Pulmonic Valve
↓
Pulmonic Artery
↓
Lungs
↓
Pulmonary Vein
↓
Left Atrium
↓
Mitral (Bicuspid) Valve
↓
Left Ventricle
↓
Aortic (Semilunar) Valve
↓
Aorta
↓
Systemic Circulation

Answer 151

A

A PaCO2 of 30-35 mmHg (moderate hyperventilation) causes vasoconstriction (arterial) and thus decreases cerebral blood volume. Decreasing the cerebral blood volume will decrease the intracranial pressure. CO2 is a potent vasodilator.

Answer 152

A

available oxygen and amount of oxygen carried by hemoglobin.

Answer 153

A

The horizontal axis is Pa02, or the amount of oxygen available. The vertical axis is SaO2, or the amount of hemoglobin saturated with oxygen.

Answer 154

A

almost flat, indicating there is little change in saturation above this point.
o So, PaO2 of 60 or more is usually considered adequate.

Answer 155

A

less than 60 mm Hg the curve is very steep, and small changes in the PaO2 greatly reduce the SaO2. The term “affinity” is used to describe oxygen’s attraction to hemoglobin binding sites.

Answer 156

A

less than 60 mm Hg the curve is very steep, and small changes in the PaO2 greatly reduce the SaO2.

Answer 157

A

oxygen’s attraction to hemoglobin binding sites.

Answer 158

A

variation in pH,
temperature,
CO2 and,
2,3,-DPG
a metabolic by-product which competes with O2 for binding site

Answer 159

A

pH at 7.4,
temperature at 37 Centigrade, and
PaCO2 at 40.
Changes from these values are called “shifts”.

Answer 160

A

increase oxygen’s affinity for hemoglobin.

o In a left shift condition (alkalosis, hypothermia, etc.) oxygen will have a higher affinity for hemoglobin.

Answer 161

A

given PaO2, but more of it will stay on the hemoglobin and ride back through the lungs without being used. This can result in tissue hypoxia even when there is sufficient oxygen in the blood.

Answer 162

A

decreases oxygen’s affinity for hemoglobin.

Answer 163

A

lower affinity for hemoglobin. Blood will release oxygen more readily.This means more O2 will be released to the cells, but it also means less oxygen will be carried from the lungs in the first place.

Answer 164

A

denatures the bond between oxygen and hemoglobin, which increases the amount of oxygen and hemoglobin and decreases the concentration of oxyhemoglobin. The dissociation curve shifts to the right.

Answer 165

A

Bohr Shift.

Answer 166

A

causing more oxygen to be given up as oxygen pressure increases and it is more pronounced in animals of smaller size due to the increase in sensitivity to acid

Answer 167

A

measurement of the heart’s efficiency and can be used to estimate the function of the left ventricle, which pumps blood to the rest of the body.

Answer 168

A

amount of blood pumped divided by the amount of blood the ventricle contains.

Answer 169

A

55% of the blood volume.

Answer 170

A

fraction of blood being ejected decreases.

Answer 171

A

100 mL that pumps 60 mL to the aorta has an ejection fraction of 60%.

Answer 172

A

Positive end expiratory pressure (PEEP) is a mode of therapy used with mechanical ventilation. At the end of exhalation the patient‟s airway pressure is maintained above atmospheric pressure. The purpose is to prevent alveolar collapse at end expiration.

Answer 173

A

o Improve functional residual capacity (FRC)

o Enhance oxygen transport (allows for > PaO2 without requiring ↑ FI

Answer 174

A

Complications
o Impaired venous return, resulting in ↓ C.O.
o ↓ venous return, ↓C.O. ↓O2 delivery even though ↑ PaO2
o Barotrauma- rupture of lung tissue. PEEP levels >15 cm H2O are considered dangerous (tension pneumo).

Answer 175

A

High pressure (Arteries) to Low pressure (Venous)

Answer 176

A

arteries.

Answer 177

A

o Supplies frontal and Parietal Lobes

o Supplies leg area of precentral gyrus

Answer 178

A

Supplies most of the basal ganglia and parts of internal capsule.

Answer 179

A

o Supplies portions of basal ganglia

o Supplies part of internal capsule.

Answer 180

A

Internal Carotid Artery

Answer 181

A

Anterior Communicating Artery

Answer 182

A

Posterior Cerebral Artery

Answer 183

A

Posterior Cerebral Artery

Answer 184

A

Posterior Cerebral Artery

Answer 185

A

Posterior Cerebral Artery

Answer 186

A

Superior Cerabellar Artery

Answer 187

A

• AICA Anterior Inferior Cerabellar Artery
Undersurface of Cerebellum and pons
•PICA Posterior Inferior Cerabellar Artery
o Undersurface of Cerebellum and Midbrain

Answer 188

A

o Sensory

o Smell

Answer 189

A

o Sensory

o Vision

Answer 190

A

o Motor
•Most EOM movement, raise eyelids
o Parasympathetic:
• Pupilary constriction, Lens shape

Answer 191

A

Motor

• Down and inward movement of the eye

Answer 192

A

o Motor
• Muscles of mastication
o Sensory
• Sensation of face and scalp, cornea, mucous membranes of mouth and nose

Answer 193

A

o Motor

• Lateral eye movement

Answer 194

A

o Motor
 Facial muscles, close eye, labial speech
o Sensory
 Taste (sweet, salty, sour, bitter) on anterior two-thirds of tongue
o Parasympathetic
 Saliva and tear secretion

Answer 195

A

o Sensory

 Hearing and Equilibrium

Answer 196

A

o Motor
 Pharynx (phonation and swallowing)
o Sensory
 Taste on posterior one-third of tongue, pharynx (gag reflex)

Answer 197

A

• Parotid gland, carotid reflex

Answer 198

A

o Motor
• Pharynx and Larynx (talking and swallowing)
o Sensory
• General sensation from carotid body, carotid sinus, pharynx, viscera
o Parasympathetic
 Carotid reflex

Answer 199

A

Motor

 Movement of trapezius and sternomastoid muscle

Answer 200

A

o Motor

 Movement of tongue

Answer 201

A

o Right mainstem intubation
o Atelectasis
o ↓ CO

Answer 202

A

o ↓ Stimulation
 ↓ sympathetic stimulation, ↓ HR, ↓ BP = ↓ ICP
 Reverse Trendelenburg
 Proper neck alignment
A flexed head will increase ICP by constricting venous drainage.

Answer 203

A

response of the subsynaptic membrane to the neurotransmitter substance that lowers the membrane potential to form an excitatory postsynaptic potential. Sodium ions rush into the neuron, whereas potassium ions leave the cell trough the postsynaptic membrane.

Answer 204

A

more difficult for it to fire.

Answer 205

A

inhibitory postsynaptic potential.

Answer 206

A

increase permeability to only potassium and chloride ions in the synaptic membrane.

Answer 207

A

motor cortex, skeletal muscle, preganglionic autonomic nerves, postganglionic parasympathetic nerves, and postganglionic sympathetic nerves to sweat glands.

Answer 208

A

motor cortex, skeletal muscle, preganglionic autonomic nerves, postganglionic parasympathetic nerves, and postganglionic sympathetic nerves to sweat glands.

Answer 209

A

 Are located in all of the postganglionic parasympathetic endings and the postganglionic sympathetic endings to sweat glands.

Answer 210

A

o Usually excitatory, and found in the postganglionic sympathetic nerves.

Answer 211

A

o Inhibitory

Answer 212

A

 Norepinephrine stimulates alpha > beta.

 Epinephrine stimulates alpha and beta equally

Answer 213

A

Dopamine; Dopaminergic receptors

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Concepts/Hemodynamics Flashcards

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