VALLEY:Echo/CO2/Ox/PN/Other

Question 1

What seven cardiac parameters are observed or estimated with two dimensional transesophageal echocardiography?

Answer 1

1) Ventricular wall motion
2) valve motion
(3) estimations of end-diastolic and end-systolic volumes (ejection fraction),
(4) Cardiac output
(5) Blood flow characteristics,
6) intracardiac air
(7) intracardiac masses.

Question 2

refers to the presence of less than normal ventricular motion

Answer 2

Hypokinesis

Question 3

Refers to the presence of greater than normal wall motion;

Answer 3

Hyperkinesis

Question 4

Absence of wall motion

Answer 4

Akinesis

Question 5

ventricle has a paradoxic outward movement.

Answer 5

Dyskinesis

Question 6

Identify the two most sensitive monitors for detection of air emboli.

Answer 6

Transesophageal echocardiography (TEE) and a Doppler probe secured over the right side of the heart are the most sensitive methods of intracardiac gas detection.

Question 7

Which method is the most sensitive for detecting venous air embolism?

Answer 7

Transesophageal echocardiography (TEE). It is 5- 10 times as sensitive as the Doppler technique.

Question 8

TEE provides visual representation of air in the

Answer 8

right or left heart. Therefore, smaller and fewer bubbles can be detected by TEE.

Question 9

Transesophageal two-dimensional echocardiography has an additional benefit: What is this benefit?

Answer 9

The added benefit of two-dimensional transesophageal echocardiography is evaluation of cardiac function.

Question 10

Transesophageal two-dimensional echocardiography has __________than precordial Doppler ultrasound for
detecting venous air embolism.

Answer 10

greater sensitivity

Question 11

What advantage does C02 monitoring have over pulse oximetry or vital sign monitoring?

Answer 11

Carbon dioxide monitoring detects acute, complete airway obstruction and extubation more rapidly than pulse oximetry or vital sign monitoring.

Question 12

Identify and describe phase I of the C02 waveform.

Answer 12

Phase I of the CO2 waveform reflects late inspiration, during which carbon dioxide levels should be near zero.

Question 13

Identify and describe phase II of the C02

waveform.

Answer 13

represents the emptying of connecting airways and the beginning of the emptying of alveoli.

Question 14

During phase 2, As exhalation continues, gas from alveoli

in regions with relatively short conducting airways

Answer 14

appears and mixes with dead space gas from regions with relatively long conducting airways, resulting in an increasing C02 level

Question 15

Phase II reflects a

Answer 15

mixture of anatomic and alveolar dead-space.

Question 16

Identify and describe phase III of the C02 waveform

Answer 16

Phase III is the alveolar plateau. Because of uneven emptying of alveoli, the slope continues to rise gently.

Question 17

Point D shows the best

Answer 17

approximation of alveolar C02 (end of expiration, beginning of inspiration, end tidal C02) .

Question 18

Identify and describe phase IV of the C02 waveform.

Answer 18

As the patient inhales, C02-free gas enters the patient’s airway, and the C02 level abruptly falls to zero.

Question 19

Phase IV is

Answer 19

inspiration.

Question 20

Interpret the a (alpha) angle of the C02 waveform.

Answer 20

angle between Phases II and III is called the a (takeoff, elevation) angle.

Question 21

Normal alpha angle _____Degrees

Answer 21

100-110 degrees.

Question 22

Angle decreased with obstructive lung disease

Answer 22

Alpha (because the dead space volume takes longer to be exhaled)

Question 23

The slope of Phase III depends on the

Answer 23

lung’s ventilation-perfusion status.

Question 24

Airway obstruction and PEEP on alpha angle ?

Answer 24

cause an increased slope and a larger a angle

Question 25

Interpret the~ (beta) angle of the CO2 waveform.

Answer 25

The angle between the end of Phase III and the descending limb of the capnogram is called the BETA angle.

Question 26

BETA angle Normally, it is approximately _____degrees.

Answer 26

90

Question 27

What issues may INCREASE the BETA angle of the C02 waveform?

Answer 27

increased with rebreathing, malfunctioning inspiratory valves, and with prolonged response time compared
to respiratory cycle time, especially in children.

Question 28

Decrease the BETA angle of the CO2 waverform associated with?

Answer 28

The beta angle will be decreased if the slope of phase III is decreased

Question 29

The capnogram baseline is elevated in the intubated patient who received a volatile agent/N20/narcotic anesthetic. Ventilation is adequate. What are the
most likely causes of the elevated C02 baseline and what do you do?

Answer 29

An elevated C02 waveform baseline indicates the patient is rebreathing, most likely due to a C02 absorbent issue or a malfunctioning unidirectional valve. Increasing fresh gas Row will lower the C02 in the circle system.

Question 30

What three conditions could cause the end-tidal C02 (ETC02) to increase in an intubated patient under general
anesthesia?

Answer 30

ETC02 will increase when: (l) C02 production exceeds ventilation, i.e., as in in hyperthermia; (2) an exogenous source of C02 is present such as C02 insufflation, bicarbonate infusion or rebreathing; (3) alveolar ventilation
decreases

Question 31

An end-tidal C02 (ETC02) partial pressure of< 5 mm-Hg is diagnostic of what?

Answer 31

Esophageal intubation

Question 32

What causes the “rippling” or “feathering”seen on the plateau of the capnogram?

Answer 32

Cardiogenic oscillations produce the feathering pattern associated with the plateau of the capnogram.

Question 33

What will happen to end-tidal C02 (ETC02) if the patient is ventilated and a ventilation:perfusion {V /Q) mismatch
develops?

Answer 33

ETC02 may decrease because the ability to blow off C02 decreases with V/Q mismatching

Question 34

Where on the capnograph tracing is found dead space plus alveolar ventilation?

Answer 34

Dead space plus alveolar ventilation is found throughout expiration on the capnograph tracing

Question 35

What gases are measured by mass spectrometry?

Answer 35

Mass spectrometry measures C02, 02, N2, and inhaled agents (N20, isoflurane, sevotlurane, destlurane, halothane, enflurane).

Question 36

When using a mass spectrometer, what is the primary concern?

Answer 36

The sampling interval, while normally short enough to provide sufficient early warning of most untoward events and physiological changes and detection of some events such as esophageal intubation, may not be short
enough and sampling rate may not be rapid enough

Question 37

What happens to the gas sample drawn from

a side port into the analyzer compartment of the mass spectrometer?

Answer 37

The gas sample is ionized by an electron beam and passed through a magnetic field.

Question 38

What happens to the ions formed by passing the gas through the electron beam of the mass spectrometer?

Answer 38

The ions formed by passing the gas through the electron beam follow a curved path as they pass through the magnetic field.

Question 39

For mass spectrometer, ions with greater mass to charge rations are

Answer 39

Least deflected and follow the curved path with the greatest radius.

Question 40

For mass spectrometer, ions with smallest mass to charge rations are

Answer 40

are DEFLECTED MOST and follow the curved path with the smallest radius.

Question 41

How is the concentration of a gas determined by the mass spectrometer?

Answer 41

Molecules of different mass are deflected at varying angles when passed through a magnetic field. Detectors are placed at specific locations to the number of molecules hitting the detector, which is then converted to
a concentration of the particular gas.

Question 42

Where should the gas monitor sampling line be placed?

Answer 42

Mass spectrometry sampling should occur from a side port on an elbow inserted between the endotracheal tube or mask and the Y-piece of a circle system.

Question 43

What three general problems can be detected by mass spectrometry?

Answer 43

identify equipment problems, (2) identify ventilatory problems (hypocapnia, hypercapnia, emboli) and (3) warn of vaporizer malfunction

Question 44

List specific problems that can be detected by mass spectrometry as far as anesthesia machine goes?

Answer 44

(I) Error in gas delivery (C02, 02, Nz, and inhaled agent analysis);

2) anesthesia machine malfunction {C02, 0 2, N2, and inhaled agent analysis); (3) disconnection (C02, 02, N2. and inhaled agent analysis);
(4) vaporizer • malfunction or contamination (inhaled agent analysis};
(5) anesthesia circuit leaks (C02 and N1 analysis);
(6) endotracheal tube cuff leak

Question 45

Other things the mass spectometry can help identify?

Answer 45

poor mask or LMA fit {C02 and N2 analysis);
(8) hypoventilation (C02 analysis);
(9) malignant hyperthermia (C02 analysis);
( 10) airway obstruction including kinked endotracheal tube ( C02 analysis); (
11) air embolism (C02 and N1 analysis); (12) circuit hypoxia {02 analysis); (13) vaporizer overdose {agent analysis

Question 46

Can the mass spectrometer detect a ventilation:perfusion (V/Q) mismatch? Explain your answer.

Answer 46

NO. V/Q mismatch is associated with a decrease in PaO2, and the mass spectometer does not assess PaO2.

Question 47

What are two limitations of a mass spectrometer?

Answer 47

l) Long measurement delays may be encountered. (2) Administration of isoproterenol with give HIGH false measurements.

Question 48

What limitation exists when using mass spectrometry with a closed system?

Answer 48

The gas sampling system may withdraw from the system more gas per minute for analysis than the volume of 02 introduced. Hypoxemia could result.

Question 49

A mass spectrometer reads 5% C02 at sea level. What is the partial pressure of CO2? What law is the basis for this
calculation?

Answer 49

(5%/100) x 760 = 38 mm-Hg; 5% C02 exerts a partial pressure of 38 mm-Hg. Dalton’s law of partial pressures is the basis for this calculation.

Question 50

Explain how a pulse oximeter works.

Answer 50

Two different wavelengths oflight are used: one is visible red light (660 nm) and the other infrared{(940 nm).

Question 51

Infrared light {940 nm) is absorbed by whereas

Answer 51

oxyhemoglobin

Question 52

Visible red light {660 nm) is absorbed by

Answer 52

deoxyhemoglobin.

Question 53

What ratio is measured with pulse ox?

Answer 53

The ratio of pulsatile to non-pulsatile light absorption

at each frequency is calculated. The ratio is then correlated to Sp02 through internal calibration.

Question 54

The most common currently used infrared wavelength is

Answer 54

940 nm.

Question 55

What two principles are combined in the pulse oximeter to measure oxygen saturation in arterial blood?

Answer 55

Pulse oximeters combine the principles of oximetry and plethysmography to measure noninvasively oxygen saturation in arterial blood

Question 56

What does a finger plethysmograph detect?

Answer 56

A finger plethysmograph uses a light-emitting diode and a photoelectric cell to detect changes in finger volume

Question 57

The Lambert-Beer law is based on what observation and applies to what monitoring modality?

Answer 57

The Lambert-Beer law is based on the observation that oxygenated hemoglobin and reduced hemoglobin differ in their absorption of red and infrared light.

Question 58

This law forms the basis of pulse oximetry

Answer 58

Lambert-Beer law

Question 59

Identify the two light sources in the photo diode of the pulse oximeter

Answer 59

Red light {660 nanometer wavelength) and infrared light (940 nanometers wavelength).

Question 60

List the absolute and relative contraindications to pulse oximetry.

Answer 60

There are no contraindications to pulse oximetry

Question 61

Why might low or poor perfusion states interfere with accurate pulse oximeter readings?

Answer 61

Pulse oximeters require adequate pulsations to distinguish light absorbed from arterial blood from venous blood and tissue light - this process is called plethysmographic analysis.

Question 62

Pulse oximeter readings may be unreliable or unavailable if

Answer 62

There is loss or diminution of peripheral pulse.

Question 63

List examples of low perfusion states that limit pulse oximetry : Mechanically related

Answer 63

Proximal BP cuff inflation
External pressure
Improper positioning

Question 64

List examples of low perfusion states that limit pulse oximetry : Patient condition

Answer 64

(4) hypotension;
{5) hypothermia;
(6) Raynaud’s phenomenon;
(7) cardiopulmonary bypass; (8) low cardiac output; (9) hypovolemia; (10) peripheral vascular disease;

Question 65

Does valsava maneuver affect pulse ox?

Answer 65

Yes such as laboring patients.

Question 66

Factors that lead to falsely low pulse oximeter readings (Sp02 < Sa02). Hgb

Answer 66

versions of hemoglobin, namely methemoglobin when the true Sa02 > 85%, and HbK;

Question 67

Factors that lead to falsely low pulse oximeter readings (Sp02 < Sa02–> DYES?

Answer 67

methylene blue, indigo carmine, isosulfan •

blue, indocynanine green, and nitrobenzene

Question 68

FACTORS that lead to false low pulse ox nail polish,

Answer 68

especially black, purple, or dark blue; and

Question 69

The pulse oximeter LED generates

Answer 69

heat

Question 70

FACTORS that lead to false low pulse ox anemia,

Answer 70

especially if the hematocrit is <25%; (S) low saturation (Sa02 < 80%)

Question 71

List two factors that lead to falsely high pulse oximeter readings (SP02 > Sa02).

Answer 71

Carboxyhemoglobin (CO poisoning) and methemoglobin-when the true Sa01 < S5% - lead to falsely high pulse oximeter reading

Question 72

Explain how the presence of methemoglobin can lead to both falsely high and falsely low pulse oximeter readings

Answer 72

Methemoglobin absorbs a significant amount of light at both 660 and 940 nm and thus the pulse oximeter detects equal amount of oxy- and deoxyhemoglobin which results in a reading of 8O% to 85%. In other words, in
the presence of significant methemoglobinemia the pulse oximeter reading is essentially “fixed” at 80% to 85%. Therefore, when the true Sa02 is less than 85%, the reading is falsely high and the obverse is true as well.

Question 73

List 5 factors the generally have no significant effect on pulse oximeter readings

Answer 73

(1) polycythemia; (2) skin pigmentation( 4) red henna dye; and, (5) jaundice.

Question 74

Hgb that DOES NOT AFFECT pulse ox?

Answer 74

(3) alternate hemoglobins, specifically HbF, HbS, HbH, and sulfHb;

Question 75

Can the pulse oximeter detect a ventilation: perfusion mismatch? Why or why not?

Answer 75

Yes. Pa02 decreases when a ventilation:perfusion mismatch develops. Since Sa02 decreases when Pa02 decreases below 100 mm Hg, a pulse oximeter can detect a ventilation:perfusion mismatch

Question 76

What is the best monitor to detect a disconnection?

Answer 76

According to Stoelting and MiJler, CAPNOGRAPHY and SPIROMETRY have the highest value in detecting disconnection.

Question 77

The next best monitors for detecting disconnection beside capnography and spirometry

Answer 77

pulse oximetry and the stethoscope

Question 78

What two measurements assess blood oxygen?

Answer 78

Pa02 and Sa02

Question 79

What is the most useful method for monitoring the effects of muscle relaxants during surgery?

Answer 79

The mechanical response elicited by the peripheral nerve stimulator is the most useful method of monitoring neuromuscular blockade

Question 80

Compare and contrast the diaphragm, laryngeal muscles, orbicularis oculi, and thumb muscles as regards response
to and recovery from (i.e., sensitivity) muscle relaxants.

Answer 80

In general, the diaphragm, laryngeal muscles, and orbicularis oculi respond to AND recover from muscle relaxants sooner than the thumb. Try this
mnemonic: “First flaccid, first firm:

Question 81

What is the frequency of stimulation in a train-of-four?

Answer 81

2 Hz (two twitches per second or one every 0.5 seconds).

Question 82

One hertz (Hz) is how many cycles per second? 50 hertz (Hz) is how many cycles per second?

Answer 82

1 Hz = 1 cycle/second. 50 hertz is 50 cycles per second

Question 83

What is post-tetanic potentiation (facilitation)?

Answer 83

Single twitch responses after tetany are transiently enhanced. The enhanced single twitch responses immediately after tetany is post-tetanic potentiation (facilitation).

Question 84

How is tetany produced with a nerve-muscle stimulator?

Answer 84

Tetany is produced by continuous electrical stimulation for five seconds at 50 Hz, which is an intense stimulus for release of acetylcholine at the neuromuscular junction

Question 85

List seven characteristics of nondepolarizin neuromuscular blockade.

Answer 85

1. Decreased twitch height
   (2) fade during tetany
   (3) train-of-four ratio < 0.7
   (4 post-tetanic potentiation, (5)augmentation of block
   by other nondepolarizing agents.

Question 86

Characteristics of NDNMB as fas as fasciculations

Answer 86

absence of fasciculations

Question 87

NDNMB as far as acetylcholinesterase inhibitors.

Answer 87

antagonism of block by acetylholinesterase inhibitors

Question 88

What is the best stimulation pattern to determine fade during neuromuscular block?

Answer 88

Double-burst stimulation (DBS} appears to be the best test to determine fade in neuromuscular block

Question 89

In DBS

Answer 89

3,3 2 trains of3 impulses at 50 Hz separated by 750 ms are given

Question 90

The response to DBS is easier to detect

Answer 90

manually,

Question 91

Response to DBS correlates well with

Answer 91

train-of-four ratios (TOF), and the DBS response may reappear earlier than TOF during intense neuromuscular block

Question 92

What percent of receptors are blocked when you have a full return of the train of- four?

Answer 92

70% can still be blocked with full train-of-four. [

Question 93

List seven characteristics of phase I depolarizing blockade.

Answer 93

Decreased twitch height, (2) absence of fade with tetany, (3) slight reduction of twitch height in train-of-four (ratio ofT4:Tl > 0.7}, (4) no post-tetanic potentiation, (5) fasciculations, (and (7)

Question 94

Phase I block and NDNMB

Answer 94

antagonism of block by nondepolarizing muscle relaxants,

Question 95

Augmentation of block by acetylcholinesterase

inhibitors: What type of block ?

Answer 95

Phase I

Question 96

Fasciculations seen with what type of block?

Answer 96

Phase I

Question 97

Decreased twitch height seen with what type of BLock

Answer 97

Phase I

Question 98

Do the characteristics of phase II block differ from those of a nondepolarizing block when using a peripheral nerve
muscle stimulator?

Answer 98

No. Phase II block is similar to nondepolarizing block. Characteristics of phase II block include fade in train-of-four, fade during tetany, and post-tetanic potentiation (facilitation

Question 99

In a hemiplegic patient, is the twitch elicited by a nerve muscle stimulator depressed more or less on the paralyzed side than on the normal side when non-depolarizing muscle relaxants are present? Explain .

Answer 99

The twitch is less depressed on the paralyzed side, presumably because of up regulation of acetylcholine receptors.

Question 100

Why is a twitch LESS Depressed on the paralyzed side of a patient with hemiplegia?

Answer 100

Because of UPREGULATION of ACH receptors.

Question 101

How is the depth of muscle blockade assessed when there is no detectable train-of-four or tetany?

Answer 101

Post- tetanic count (PTC) is used to evaluate the degree of neuromuscular blockade when there is no reaction to single twitch or train-of-four (TOF) nerve stimulation.

Question 102

How is the post-tetanic count done?

Answer 102

Fifty Hz tetanus is applied for five seconds, followed by
a three-second pause and then stimulation at 1 Hz. The train-of-four and tetanic responses are undetectable but facilitation produces a certain number of visible post-tetanic twitches

Question 103

For a given drug, the number of visible twitches correlates how?

Answer 103

inversely with the time required for the return of single

twitch or train-of-four responses.

Question 104

Discuss the 5 tests to determine the adequacy of neuromuscular block reversal.

Answer 104

(1) train-of-four > or equal 0.7,
(2) head lift for 5 seconds
(3) adequate tidal volume and/or vital capacity
(4) negative inspiratory pressure of 50 cm H20
(5) hand grasp strength

Question 105

Least sensitive at determine the adequacy of neuromuscular block reversal.

Answer 105

adequate tidal volume and/or vital capacity are the least sensitive tests of adequate NMB reversal (70-80% receptor block remains).

Question 106

Recent research has indicated, however,

that a TOF > 0.7 does not indicate adequate NMB reversal and the new criterion is TOF

Answer 106

0.8-0.9 to exclude clinically significant neuromuscular

block.

Question 107

What tests of neuromuscular block correlate well with a TOF > 0.8-0.9?

Answer 107

double-burst stimulation, and holding a tongue depressor blade between the teeth. Double-burst stimulation (DBS) appears to provide a better tactile response to fade, and the DBS3,3 pattern seems to be a more reliable assessment of muscle relaxant reversal (Duke)

Question 108

The ability to hold a tongue depressor between the teeth correlates with a

Answer 108

TOF > or equal to 0.86 and thus is an excellent assessment of adequate neuromuscular block reversal

Question 109

A TOF > or equal 0.9 cannot be determined by

Answer 109

feel; it must be quantitated by mechano-, electro-,

or acceleromyography.

Question 110

Double-burst stimulation (DBS) appears to provide a better

Answer 110

tactile response to fade, and the DBS3,3 pattern seems to be a more reliable assessment of muscle relaxant reversal

Question 111

How many twitches in a train-of-four should be visible, after administering a nondepolarizing neuromuscular blocker, before endotracheal intubation should be attempted?

Answer 111

The patient should be intubated 30 to 60 seconds after all twitches in the train-of-four have disappeared. No twitches should be seen when the trachea is intubated.

Question 112

What site(s) gives the most reliable approximation of core body temperature?

Answer 112

The lower 25% of the esophagus give a reliable approximation of blood and cerebral temperature

Question 113

Correlates well with esophageal TEMP which is the best is these 2 methods?

Answer 113

The tympanic membrane and aural canal temperatures

correlate well with esophageal temperature

Question 114

The most accurate reflection of temperature is a

Answer 114

pulmonary artery catheter (PAC) thermistor (never used for this purpose)

Question 115

Where is the ideal placement of the esophageal stethoscope?

Answer 115

lower third of the esophagus.

Question 116

The use of an esophageal stethoscope is contraindicated in patients with either of what two conditions?

Answer 116

The patient who has an esophageal perforation and the patient with liver disease who has or could have esophageal varices. Do not instrument the
esophagus of these patients.

Question 117

Describe the basic operation of a forced-air warmer.

Answer 117

A forced-air warmer (such as the Bair Hugger•, Arizant Healthcare) entrains ambient air through a microbial filter. The air is warmed using an thermostat-controlled electric heater, and then blown through a hose that is connected to an inflatable patient cover.

Question 118

Forced-air warmers are also known as

Answer 118

convection warming devices and warm air blowers.

Question 119

List two standard for forced-air warming devices.

Answer 119

The U.S. standards for forced-air warming devices (2002) are (1) the maximum contact surface temperature shall not exceed 48 °C, and (2) the average contact surface temperature shall not exceed 46 °C during normal
conditions.

Question 120

State advantages afforded by forced-air warmers.

Answer 120

Forced-air warming is safe, simple, effective, and inexpensive

Question 121

Can be warmed before use with a forced-air device.

Answer 121

Fiberoptic laryngoscopes

Question 122

List some disadvantages of forced-air warmers.

Answer 122

Electric power requirements
must occasionally be removed from the patient to
expose covered areas

Question 123

Define perioperative blood salvage (CELL SAVER)

Answer 123

Perioperative blood salvage refers to the recovery of shed blood from the surgical field or wound drains and re-administration to the patient.

Question 124

In most instances, the process involves “washing” of the salvaged material with return of

Answer 124

only the RBC component of blood

Question 125

List seven situations in which intraoperative blood salvage (IBS) may be employed

Answer 125

(1) cardiovascular surgical procedures, (2) aortic
reconstruction, (3) spinal instrumentation, (4) joint arthroplasty, (5) liver transplantation, (6) resection of arteriovenous malformations, and (7) occasionally in the management of trauma patient.

Question 126

Briefly describe the operation of contemporary

“cell saver” (blood salvage) devices.

Answer 126

Contemporary “cell saver” devices anti-coagulate the salvaged blood as it leaves the surgical field, separate the RBCs from other liquid and cellular elements by centrifugation, and then wash the salvaged RBCs extensively with saline.

Question 127

Cell saver separate the RBCs from other liquid and cellular elements by

Answer 127

CENTRIFUGATION.

Question 128

What is the hematocrit range of the salvaged blood aliquots returned to the patient?

Answer 128

The RBCs are typically returned to the patient suspended in saline in aliquots of 125 or 225 mL with a hematocrit of 45 to 65%.

Question 129

How efficient is the modern cell saver? How many RBCs are salvaged.

Answer 129

Approximately 5O% of RBCs are salvaged, therefore anticipate administration of allogenic blood.

Question 130

What are the contraindications to intraoperative

blood salvage?

Answer 130

infection, malignant cells, urine, bowel contents, or amniotic fluid in the operative field.

Question 131

Identify expected complications of intraoperative

blood salvage.

Answer 131

The potential complications of intraoperative blood salvage (IBS) are a function of the reinfusion of materials that might remain after the washing process.

Question 132

Cell saver ,Most of these are in fact removed quite efficiently by contemporary cell salvage

Answer 132

fat microaggregates such as platelets and leukocytes, air, red cell stroma, free hemoglobin, heparin, bacteria, and debris from the surgical field.

Question 133

What coagulopathy is expected after intraoperative

blood salvage?

Answer 133

Dilutional coagulopathy is to be expected after intraoperative blood salvage because the washing process removes essentially all clotting factors and most platelets.

Question 134

How woul you manage this coagulopathy?

Answer 134

Management is the same as for a dilutional coagulopa·

thy occurring with administration of homologous or preoperative autologous donation (PAD) blood

Question 135

Briefly describe the basic operation of heat and moisture exchanger (HME).

Answer 135

A heat and moisture exchanger (HME) conserves some exhaled water and heat and returns them to the patient in the inspired gas.

Question 136

The HME is also known as a

Answer 136

condenser humidifier
Swedish nose (!).
Artificial nose
nose humidifierpassive humidifier, regenerative humidifier,
moisture exchanger, and vapor condense

Question 137

What are the indications for heat and moisture exchanger (HME) use?

Answer 137

increase inspired heat and humidity during both short- and long-term ventilation.

Question 138

HMEs are indicated if the patient is

Answer 138

hypothermic and for use in the neonatal circuit. HMEs may be especially useful in transporting the intubated patients.

Question 139

List two contraindications to heat and moisture exchanger (HME) use

Answer 139

(1) patients with thick and copious, or bloody secretions, (2) patients with a leak that prevents exhaled gas from passing through the HME