Exam 1- Clinical Monitoring (6/8/23)

Question 1

AANA Monitoring Standards for Oxygenation

Answer 1

• Clinical Observation (watch your patient)
• Continuous Pulse Oximetry
• ABG’s as indicated

Question 2

AANA Monitoring Standards for Ventilation

Answer 2

• Auscultation
• Chest excursion (rise/fall of chest)
• ETCO2 documentation
• Pressure monitors as indicated
• Monitor RR q 5 mins

Question 3

AANA Monitoring Standards for Cardiovascular System

Answer 3

• Electrocardiogram
• Auscultation as needed
• BP and HR documentation q 5 mins

Question 4

AANA Monitoring Standards for Thermoregulation

Answer 4

• When clinically significant changes in body temp are anticipated or suspected
• Continuous monitor of temperature in cases longer than 20 minutes, pediatric cases, or elderly patients.

Question 5

AANA Monitoring Standards for Neuromuscular System

Answer 5

• When neuromuscular blocking agents are administered.
• TOF are charted q 15 mins

Question 6

Name factors that will cause the Hb dissociation curve to shift right.

Name factors that will cause the Hb dissociation curve to shift left

Answer 6

Remember:
Right shift = ↓ Hb affinity to O2.
Left shift = ↑ Hb affinity to O2

Question 7

How low can a healthy normal adult patient’s PaO2 decrease before their O2 saturation drops below 90%?

Answer 7

PaO2 can decrease to 60 mmHg before O2 saturation drops below 90%.

Question 8

Upon what law of physics is pulse oximetry based?

Answer 8

• Beer-Lambert Law

Question 9

Explain how concentration of a solute affects light absorption in pulse oximetry.

Answer 9

• Amount of light absorbed is proportional to the concentration of the light absorbing substance (Beer’s Law)
• Higher Hb concentration, more light absorption

Question 10

Explain how distance affect light absorption in pulse oximetry.

Answer 10

• Amount of light absorbed is proportional to the length of the path that the light has to travel in the absorbing substance (Lambert’s Law)
• Wider arteries, more light absorption

Question 11

What were the four species of Hb in adult blood discussed in lecture?

Answer 11

• Oxyhemoglobin (O2Hb)
• Deoxyhemoglobin (deO2Hb)
• Methemoglobin (metHb)
• Carboxyhemoglobin (COHb)

Question 12

What is considered the gold standard for SaO2 measurements and is relied on when pulse oximetry readings are inaccurate or unobtainable?

Answer 12

• CO-oximetry

Question 13

The wavelength of red light

Answer 13

• 660 nm

Question 14

The wavelength of infrared light

Answer 14

• 940 nm

Question 15

__________ absorbs more infrared light.

___________ absorbs more red light.

Answer 15

SeXy DARLing:
SiX hundred wavelength, DeoxyHb Absorbs Red Light.

Question 16

How does the amount of oxyhemoglobin and deoxyhemoglobin in the blood affect oxygen saturation?

Answer 16

• As the amount of oxy Hb and deoxy Hb changes, the light ratio comparing red and infrared light also changes.
• The pulse oximeter uses the ratio to work out the oxygen saturation.
• More DeoxyHb present, ↑ Red Light: Infrared Light Absorption Ratio, ↓ O2 sat

Question 17

Which Hb species absorbs as much light in the 660 nm range as OxyHb?

Answer 17

• Carboxyhemoglobin

The absorption of light at 660 nm by COHb is similar to that of O2Hb. At 940 nm, COHb absorbs virtually no light. Thus, in a patient with carbon monoxide poisoning, the SpO2 will be falsely elevated.

Question 18

Each 1% increase in COHb will increase SpO2 by _____%.

Answer 18

• 1%

Question 19

Many smokers have > ______% of COHb.

Answer 19

• 6%

Question 20

Schematic of the Pulse Principle.

Answer 20

• Light absorption through tissue is characterized by a pulsatile component (AC) and a non-pulsatile component (DC).
• The pulsatile component of absorption is due to arterial blood. The non-pulsatile component is due to venous blood and the remainder of the tissues.

Question 21

What factors cause signal artifacts in pulse oximetry?

Answer 21

• Ambient light
• Low perfusion
• Venous blood pulsations
• Additional light absorbers (methylene blue)
• Additional forms of Hb
• Nail polish

Question 22

How accurate is pulse oximetry when measured against ABGs as long as the patient’s O2 saturation is >70%?

Answer 22

• Pulse oximetry’s accuracy is within 2% of an ABG.

Question 23

List advantages of pulse oximetry. (Long list, common sense)

Answer 23

• Accurate/ Convenient
• Not affected by anesthetic vapors
• Noninvasive
• Continuous
• May indicate decreased cardiac output
• Tone modulation
• Probe variety (Ear probe)
• Battery-operated/ Cheap

Question 24

List disadvantages of pulse oximetry. (Long list, common sense)

Answer 24

• Poor function with poor perfusion
• Delayed hypoxic event detection
• Erratic performance with dysrhythmias
• Inaccuracy with different hemoglobin (COHb)
• Inaccuracy with dyes
• Optical interference
• Nail polish and coverings
• Motion artifact

Question 25

Fingers are relatively sensitive to ________

Answer 25

• vasoconstriction

Question 26

What kind of nails inhibit pulse oximeter transmission?

Answer 26

• Dark polish or synthetic nails

Question 27

True/False: Pulse Oximetry detection of desaturation and resaturation from the periphery is slow.

Answer 27

• True

Question 28

Why shouldn’t the pulse oximeter be placed on the index finger?

Answer 28

• ↑ risk of corneal abrasion

Question 29

Where will you place a pulse oximeter for the most accurate reading during an epidural block?

Answer 29

• Toes

Toes will be more dilated than fingers with an epidural block.

Question 30

What three parts of the body are least affected by vasoconstriction and will reflect desaturation quickly?

Answer 30

• Tongue
• Cheek
• Forehead

Question 31

Most indirect methods of blood pressure measurement utilize a sphygmomanometer. What is the series of audible frequencies produced by turbulent flow beyond the partially occluded cuff called?

Answer 31

• Korotkoff sounds

Question 32

Describe the phases of the Korotkoff sounds.

During what phase will you hear SBP and DBP?

Answer 32

• Phase I: the most turbulent/audible (SBP)
• Phase II: softer and longer sounds
• Phase III: crisper and louder sounds
• Phase IV: softer and muffled sounds
• Phase V: sounds disappear (DBP)

Question 33

Give the formula to calculate MAP

Answer 33

• MAP = DBP + 1/3 (SBP - DBP)

Question 34

What factors will limit BP auscultation?

Answer 34

• Decrease peripheral flow (shock/vasoconstriction)
• Changes in vessel compliance (atherosclerosis)
• Incorrect cuff size
• Obesity

Question 35

What is the best way to measure BP in pediatric patients?

Answer 35

• Use the automatic NIBP

Question 36

Blood pressure cuff bladder should should be ____% of arm circumference and _____ % of length of upper arm.

Answer 36

• Blood pressure cuff bladder should should be 40% of arm circumference and 80% of length of upper arm.

Question 37

What method is used by many automatic NIBP devices to measure blood pressure non-invasively.

Answer 37

• Oscillometry

Automatic NIBP correlates well with invasive BP in healthy pts.

Question 38

What factors will cause errors in automatic NIBP resulting in low SBP and high DBP?

Answer 38

• Atherosclerosis
• Edema
• Obesity
• Chronic HTN

Question 39

What will be the result of a BP reading if the patient’s BP cuff is too large?

Answer 39

• falsely low BP

Question 40

What will be the result of a BP reading if the patient’s BP cuff is too small?

Answer 40

• falsely high BP

Question 41

For standards of automatic NIBP they must be within how many mmHg?

Answer 41

• +/- 5 mmHg

Deviations up to 20 mmHg are acceptable

Question 42

What part of the arm is preferable in obese patient when measuring their BP?

Answer 42

• Forearm

Question 43

What are advantages of automatic NIBP?

Answer 43

• Eliminate clinician subjectivity
• Improved quality and accuracy
• Automaticity
• Noninvasive

Question 44

What are disadvantages of automatic NIBP?

Answer 44

• Unsuitable in rapidly changing situations
• Patient discomfort
• Complications (Compartment syndrome, Pain, Limb edema, etc)

Question 45

Caution use of automatic NIBP in:

Answer 45

• Severe coagulopathies
• Peripheral neuropathies
• Arterial/venous insufficiency
• Recent thrombolytic therapy

Question 46

List indication for an arterial line.

Answer 46

• Continuous, real-time
• Planned pharmacologic manipulation
• Repeated blood sampling
• Determination of volume responsiveness
• Timing of balloon pump counterpulsation

Question 47

Monitoring sites with arterial line.

Answer 47

• Radial (most common, easy to access)
• Ulnar
• Brachial
• Axillary
• Femoral
• Posterior tibial
• Dorsalis pedis

Question 48

What test is used to assess collateral blood flow to the hands before radial arterial line placement.

Answer 48

• Allen’s Test
• Good circulation: Color returns <5 seconds
• > 10 seconds indicate severely reduced collateral flow

Predictive value of this test is poor

Question 49

Describe the Seldinger technique for arterial placement.

Answer 49

Question 50

Describe the Transfixion technique for arterial placement.

Answer 50

• Front and back walls are punctured intentionally
• Needle removed
• Catheter withdrawn until pulsatile blood flow appears and then advanced

Question 51

When placing an arterial line, the needle should enter at a _______ degree angle (range) to the skin directly over the point at which the pulse is palpated.

Answer 51

• 30 to 45 degrees

Question 52

What is used to prevent thrombus formation in an arterial line?

Answer 52

• 1-3 ml/hr automatic NS flush (pressure bag)

Question 53

What does zeroing an arterial line do?

Answer 53

• The measuring system must also be zeroed to obtain accurate data.
• Zeroing the system provides a reference point of pressure.
• Most commonly, this is atmospheric pressure.

Question 54

Where is the arterial line leveled?

Answer 54

• Aortic root (mid axillary chest)

Question 55

How can the waveform of an arterial line be maximized?

Answer 55

• Limit stopcocks
• Limit tube length
• Use non-distensible tubing (hard tubing)

Question 56

Label parts 1-6 of the arterial waveform.

Answer 56

• 1: systolic upstroke
• 2: systolic peak pressure
• 3: systolic decline
• 4: dicrotic notch (closing of the aortic valve)
• 5: diastolic runoff
• 6: end-diastolic pressure

SBP is measured at 2 and the DBP is measured at 6.

Question 57

As the pressure wave moves to the periphery, what happens to the:

Arterial upstroke
Systolic Peak
Dicrotic notch
End Diastolic pressure

Answer 57

• Arterial upstroke will be steeper
• Systolic Peak will be higher
• Dicrotic notch will appear later
• End Diastolic pressure will be lower

Question 58

What causes the difference in morphologies of arterial pressures measured at different sites?

Answer 58

• Impedance and harmonic resonance along the vascular tree

Question 59

What two waves make up a typical pressure wave (summation wave)?

Answer 59

• Fundamental wave
• Harmonic wave

Question 60

What is the square wave test?

Answer 60

• The arterial line can measure BP inaccurately unless properly calibrated.
• Rapidly flushing the line generates a square wave.
• Counting oscillations after the square wave indicates that the arterial line works properly.
• There should be no more than two oscillations after the fast flush

Question 61

Describe an under-dampened arterial waveform.

Answer 61

• Systolic pressure is falsely high
• > 2 oscillations
• Multiple dicrotic notches

Question 62

Describe an over-dampened arterial waveform

Answer 62

• Systolic pressure is falsely low
• No oscillations
• Absence of dicrotic notch
• Loss of detail
• Falsely narrowed pulse pressure, but accurate MAP

Question 63

What factors affect pressure gradient changes in arterial waveforms?

Answer 63

• Age: lack of distensibility
• Atherosclerosis
• Peripheral vascular resistance changes
• Septic shock
• Hypothermia

Question 64

Compare the arterial waveforms between a normal young person and an elderly person.

Answer 64

• The elderly patient will have an ↑ SBP
• The elderly patient will be a widened Pulse Pressure
• This is due to the decrease in distensibility in the elderly patient

Question 65

Pathologic changes in peripheral vascular resistance may also produce generalized arterial pressure gradients that can affect the site choice for arterial pressure monitoring. In patients receiving vasopressor infusions for septic shock, the femoral arterial pressure may exceed the radial pressure by greater than ______ mm Hg.

Answer 65

• 50 mmHg

Miller pg. 1164

Question 66

Compare the pressure gradient changes during hypothermia and rewarming.

Answer 66

• During hypothermia, vasoconstriction causes systolic pressure in the radial artery to exceed that in the femoral artery.
• During rewarming, vasodilation reverses the gradient.

Miller pg. 1164

Question 67

List arterial line complications.

Answer 67

• Distal ischemia or pseudoaneurysm
• Hemorrhage, hematoma (hold pressure longer)
• Arterial embolization (Art line staying in too long)
• Local infection
• Peripheral neuropathy

Question 68

Cyclic arterial BP variations d/t respiratory-induced changes in intra-thoracic pressure are related to what two factors?

Answer 68

• Positive pressure ventilation
• Lung volume changes

Question 69

During the EARLY inspiratory phase of PPV, the increase in intrathoracic pressure simultaneously _______ LV afterload while _________ total lung volume, which displaces blood from the pulmonary venous reservoir forward into the left side of the heart and _________ LV preload.

Answer 69

During EARLY the inspiratory phase of PPV, the increase in intrathoracic pressure simultaneously decreases LV afterload while increasing total lung volume, which displaces blood from the pulmonary venous reservoir forward into the left side of the heart and increases LV preload.

Miller pg. 1167

Question 70

During the EARLY inspiratory phase of PPV, the increase in LV preload and decrease in afterload produce an increase in what three variables?

Answer 70

• ↑ LV SV
• ↑ CO
• ↑ Systemic arterial pressure

Miller pg. 1167

Question 71

Rising intrathoracic pressure impairs systemic venous return and RV preload; this will ________ RV afterload by slightly increasing pulmonary vascular resistance. These effects combine to reduce RV ejection during the early phase of inspiration.

Answer 71

Rising intrathoracic pressure impairs systemic venous return and RV preload; this will increase RV afterload by slightly increasing pulmonary vascular resistance. These effects combine to reduce RV ejection during the early phase of inspiration.

Miller pg. 1167

Question 72

What happens to RV stroke volume during the early phase of inspiration?

Answer 72

• RV SV drops

Question 73

What is the overall effect of increasing intrathoracic pressure on cardiac output?

Answer 73

• ↑ Intrathoracic Pressure = ↓ CO
  Memorize the flowchart

Question 74

During the expiratory phase, the decreased stroke volume ejected from the RV during inspiration travels through the pulmonary vascular bed and enters the left heart, reducing what three variables?

Answer 74

• ↓ LV filing
• ↓ LV SV
• ↓ Systemic arterial pressure

Question 75

The cycle of increasing and decreasing stroke volume and systemic arterial blood pressure in response to inspiration and expiration is known as _________________.

Answer 75

• Systolic pressure variation (SPV).

Question 76

In mechanically ventilated patients, normal SPV is __________ mmHg (range).

Answer 76

• 7-10 mmHg

Question 77

What is a normal Δ up SPV?

Answer 77

• 2-4 mmHg

Question 78

What is a normal Δ down SPV?

Answer 78

• 5-6 mmHg

Question 79

What does an increased SPV indicate?

Answer 79

• Patient may be volume responsive
• Patient may have residual preload reserve
• Possible early indicator of hypovolemia
• Critically ill patients will have an increased SPV with a drastic Δ down component.

Question 80

This variable is used as a dynamic indicator of preload reserve by utilizing the max and min pulse pressure over the entire respiratory cycle.

Answer 80

• Pulse Pressure Variation

Question 81

What is considered a normal pulse pressure variation?

Answer 81

• < 13-17%

PPV >13-17% will indicate a positive response to volume expansion

Question 82

PPV formula

Answer 82

[Maximum difference in arterial pulse pressure] / [ Average of Max and Min pulse pressure]

Question 83

The changes in stroke volume between the inspiratory and expiratory phases of positive pressure ventilation.

Answer 83

• Stroke Volume Variation

Question 84

How do you calculate SSV?

Answer 84

(SV max - SV min) / SV mean

Question 85

What is normal SVV?

Answer 85

• Less than 10-13%

SVV >10-13% indicates a positive response to volume expansion.

Question 86

SVV uses computer analysis of arterial pulse pressure waveforms and correlates resistance and compliance based on what two factors?

Answer 86

• age
• gender

Question 87

Mechanical ventilation should have a tidal volume of ______ (range).

Answer 87

• 8-10 mL/kg

Question 88

To predict accurate results of residual preload reserve through SPV, PPV, and SVV, what factors need to be met in mechanically vented patients?

Answer 88

• Tidal volume of 8 to 10 mL/kg
• Positive end-expiratory pressure ≥ 5 mm Hg
• Regular cardiac rhythm
• Normal intra-abdominal pressure
• A closed chest

Miller pg. 1168

Question 89

What is the importance of the Frank-Starling Law?

Answer 89

• Left ventricular filling determines the left ventricular end-diastolic volume (LVEDV), which is generally directly proportional to left ventricular preload and CO.
• The Frank–Starling Law describes the relationship between LVEDV and CO.
• According to the Starling Law, CO increases with increasing left ventricular preload.