Anesthesia Gas Monitoring

Question 1

Patient Safety: Guiding Concern in Development of Monitors

Answer 1

• Oxygen concentration
• disconnect alarms
• end tidal CO2
• pulse ox
• peak pressure monitoring
• anesthesia gas monitoring
• -N2O
• -desflurane
• -sevo
• -iso
• -oxygen
• -CO2
• -nitrogen

Question 2

Prevention and Detection

Answer 2

-most adverse outcomes come from misuse by practitioner and/or failure to detect equipment failure when it happens

Question 3

Non diverting gas monitor

Answer 3

• Mainstream, in-line
• sensor is located directly in the gas stream
• only CO2 and oxygen are monitored with this mode (cannot monitor volatile gases)
• oxygen: fuel cell (electrochemical)
• CO2 infrared

Question 4

Diverting gas monitor

Answer 4

-sidestream
-gas is aspirated from sampling site and through a tube to sensor located inside or on top of machine
-ALL gases can be monitored this way
oxygen: paramagnetic
volatiles, nitrous oxide, and CO2 infared

Question 5

Infrared Analysis (Diverting or NonDiverting)

Answer 5

• most often used analysis for CO2, nitrous oxide and volatile agents
• molecules containing dissimiliar atoms will absorb infrared radiation
• this technology does NOT work for oxygen and nitrogen
• tend to underestimate inspired levels and overestimate expired levels at high respiratory rates

Question 6

Infrared Analysis

Answer 6

-most molecules will absorb infrared at specific wavelengths and hence the molecule can be identified and its concentration measured

Question 7

Beer-Lambert Law

Answer 7

• absorption is according to this
• there is a logarithmic dependence between the transmission of light through a substance and concentration of that substance

Question 8

IR Side Stream Sampling Diverting

Answer 8

• continuously aspirates a sample of the gas from patient circuit, usually near where breathing circuit is connected to the airway device
• 50-250 ml/min aspirated (may be returned to patient or to scavenging)
• sample direct to place between infrared emitter, optical filter, and infrared detector, which outputs a signal proportional to remaining infrared energy not absorbed by the gases
• to quantify and identify multiple gases simultaneously multiple optical filters are required
• detected signal then amplified and interpreted via microprocessors

Question 9

The Good on side stream sampling

Answer 9

• automatical calibration and zeroing
• quick response time and short warm up
• minimal added dead-space
• low potential for cross-contamination between patients

Question 10

What could be better on side stream sampling

Answer 10

• multiple places that leaks may occur
• more variability in CO2 readings than with in line sampling- accurate with RR 20-40, decreased with increased rate
• slower response to changes than with in line sampling
• water contamination (water traps)

Question 11

Gas Monitoring

Answer 11

-to monitor CO2 the sensor must be positioned between the patient and the circuit, ideally closest to the patient end as possible
why- dead space

Question 12

Dead space: wasted ventilation

Answer 12

-ventilated areas which do not participate in gas exchange

Total deadspace= anatomic + alevolar + mechanical

Question 13

Anatomic deadspace

Answer 13

-airways leading to alveoli

Question 14

Alveolar deadspace

Answer 14

-ventilated areas in lungs without blood flow

Question 15

Mechanical deadspace

Answer 15

-artificial airways including ventilator circuits

Question 16

Inspired Oxygen Analysis

Answer 16

• FiO2 monitor is extremely important in patient safety
• first line of defense against detecting hypoxic mixtures
• but.. ventilation and oxygenation must be considered as two separate entities
• pulse oximetry is a late indicator of hypoxemia

Question 17

Low V/Q

Answer 17

-shunt perfusion: alveoli perfused but not ventilated

ET tube in mainstream bronchus

Question 18

V/Q= .8

Answer 18

normal

alveoli perfused and ventilated

Question 19

High V/Q

Answer 19

deadspace ventilation
-alveoli ventilated but not perfused
(cardiac arrest)

Question 20

Two types of oxygen analyzers

Answer 20

1. Paramagnetic (Diverting)
   - more expensive, no need to calibrate, fast enough to differentiate oxygen concentrations
2. Electrochemical (Non Diverting)
   - galvanic (fuel cell)
   - calibration needed

Question 21

Paramagnetic Oxygen Analysis

Answer 21

• unpaired electron in the oxygen molecule is attached to magnetic field
• when oxygen passed through magnetic field it goes to the strongest portion of that field
• expansion, contraction of the gas creates a pressure wave that is a proportional to the oxygen’s partial pressure

Question 22

Paramagnetic Oxygen Analyzers

Answer 22

• both inspired and end tidal oxygen levels to be measured even at rapid respiratory rates
• auto calibrates with reference gas (air or known concentration oxygen)
• many monitors combine diverting IR analysis of CO2, volatiles and nitrous oxide with a paramagnetic oxygen analysis using the same side stream sample

Question 23

Electrochemical Oxygen Analysis (Fuel cell or Galvanic)

Answer 23

• oxygen diffuses through sensor membrane and electrolyte to cathode ray tube
• reduced there (gains electrons), allowing a current to flow
• rate at which oxygen enters cell and generates current is proportional to the partial pressure of the gas outside of the membrane

Question 24

Electrochemical Oxygen Analyzer

Answer 24

-usually placed on or near the carbon dioxide canister on the inspiratory side
the good: cheaper
the bad: calibration every 8 hours, need frequent changing

Question 25

End-tidal CO2 monitoring

Answer 25

• validation of proper endotracheal tube placement
• detecting and monitoring of respiratory pathophys
• hyper/hypoventilation
• cardiac function, circuit disconnection or leaks
• adjustment of parameter settings in mechanically ventilated patients
• Estimate PaCO2

Question 26

ETCO2 and cardiac resuscitation

Answer 26

-Non survivors- average ETCO2: 4-10 mmHg
Survivors (to discharge): average ETCO2: >30 mmHg
-if patient is intubated and pulmonary ventilation is consistent with bagging, ETCO2, will directly reflect CO
-flat waveform can establish PEA
-configuration of waveform will change the obstruction

Question 27

Increase in ETCO2

Answer 27

• increased muscular activity (shivering), MH
• increased CO (during resuscitation)
• bicarbonate infusion
• tourniquet release
• effective drug therapy for bronchospasm
• decreased minute ventilation

Question 28

Decrease in ETCO2

Answer 28

• decreased muscular activity (muscle relaxants)
• hypothermia
• decreased CO (cardiac arrest)
• pulmonary embolism
• bronchospasm
• increased minute ventilation

Question 29

normal arterial CO2:

paCO2 values

Answer 29

35-45 mmHg

4. 7-6.0 kPA
5. 6-5.9%

Question 30

ETCO2

Answer 30

-capnograph
30-43 mmHg
4.0-5.7 kPa
4-5.6%

Question 31

Capnography

Answer 31

• measurement and display of both ETCO2 value and capnogram (CO2 waveform)
• mesaured by capnograph
• **picture of waveform

Question 32

Capnometry

Answer 32

• measurement and display of ETCO2 value (no waveform)

- measured by capnometer

Question 33

Value of capnogram

Answer 33

• provides validation of ETCO2 value
• visual assessment of patient airway integrity
• verification of proper ETT placement
• assessment of ventilator/breathing circuit integrity

Question 34

Quantitative vs. Qualitative ETCO2

Answer 34

Quantitative: provides actual numeric vale, found in capnographs and capnometer
Qualitative: only provides range of values, termed “CO2 Detector”

Question 35

Draw normal CO2 waveform and label parts

Answer 35

-A-B baseline
B-C expiratory upstroke
C-D expiratory plateau
D- ETCO2 value
D-E inspiration begins

Question 36

CO2 with esophageal intubation

Answer 36

-little or no CO2 is present

Question 37

CO2 waveform with inadequate seal around ETT

Answer 37

cause: leaky or deflated ET or trach cuff

- artificial airwway too small for patient

Question 38

Hypoventilation causes what in ETCO2?

Answer 38

Increase in ETCO2
-possible cause:
decreased RR
decreased TV
increased in metabolic rate
rapid rise in body temp

Question 39

Rebreathing– possible cause

Answer 39

faulty expiration valvue
inadequate inspiratory flow
insufficient expiratory flow
malfunction of CO2 absorber system

Question 40

Obstruction-possible causes

Answer 40

kinked or occluded artificial airway
presence of foreign body in the airway
obstruction in expiratory limb of breathing circuit
bronchospasm

Question 41

Spontaneous breathing Effort with Controlled Ventilation

Answer 41

-curare cleft:
appears when muscle relax being to subside
-depth of clef is inversely proportional to degree of drug activity

Question 42

Sudden loss of waveform

Answer 42

#1 thought= airway disconnection
-apnea, airway obstruction, dislodged airway, ventilator malfunction, cardiac arrest

Question 43

Colormetric CO2 detector

Answer 43

• NOT A MONITOR
• uses chemically treated paper that exchanges color hen exposed to CO2
• must match color to a range of values
• requires 6 breaths before determination
• gold is golden*