Savenging

Question 1

Who makes standards for recommended levels of anesthetics gases in OR?

Answer 1

NIOSH (National Institute for Occupational Safety and Health)

Question 2

What are NIOSH’s standards for halogenated anesthetic alone in OR?

Answer 2

2 ppm

Question 3

What is NIOSH’s standard for level of NO in OR?

Answer 3

25 ppm

Question 4

What is NIOSH’s standard for volatile agent with NO in OR?

Answer 4

0.5ppm

Question 5

What are the 5 basic components of the scavenging system?

Answer 5

1) Gas Collecting Assemby
2) Transfer means
3) Scavenging Interface
4) Gas Disposal tubing
5) Gas disposal assembly

Question 6

Describe the gas collecting assembly.

Answer 6

• Captures excess gases at site of emission
• Delivers them to transfer means tubing
• Outlet connection is 30 mm (19 on older machine) male-fitting
• Size of connections is important so that it doesn’t connect with other components of breathing system

Question 7

Describe the transfer means

Answer 7

• 2nd piece
• Also called exhaust tubing, hose and transfer system
• Conveys gas from collecting assembly to the interface
• Usually a tube with femalt-fitting connetors on both ends
• Tubing is short and large diameter, to carry high flow of gas with out significant increase in pressure
• Must be kink resistant
• Must be different than breathing tubes - may be color coded and stiffer plastic

Question 8

Describe Scavenging Interface

Answer 8

• third piece in system
• Prevents pressure increases or decreases in scavenging system from being transmitted to breathing system
• Also called balancing valve or balancing device
• Interface limits pressure immediately downstream of gas-collecting assembly to between 0.5-3.5 cmH2o
• Inlet 30 mm male connector
• Should be situated as close to gas-collecting assembly as possible
• 3 basic elements
  
  • 1)positive pressure relief
  • 2)negative pressure relief
  • 3)reservoir capacity

Question 9

What are 3 basic elements for scavenging interface and their purpose?

Answer 9

1) Positive pressure relief
* protects pt and equipment in case of occlusion of system
2) Negative pressure relief
* limit sub atmospheric pressure
3) Reservoir capacity
* matches intermittent gas flow form gas collecting assembly to the continuous flow of disposal system

Question 10

What are the two type of scavenging interfaces?

Answer 10

Open and closed

Question 11

What is an open interface for a scavenging unit?

Answer 11

• No valves
  
  • open to atmosphere via relief ports in reservoir, avoiding buildup of positive and negative pressure
• Require vacuum
• Require reservoir
• Gas enters at top of canister and travels through inner tube to base
• Vacuum control can be adjusted- varies level of suction on canister/reservoir.
  
  • Must be > FGF rate to prevent OR pollution

Question 12

What is a closed interface for the scavenging unit?

Answer 12

Two types

1. Positive pressure relief only -

• single positive pressure valve opens when max pressure reached -
• Passive disposal
  
  • no vacuum used, no reservoir bag needed

2. Positive pressure and negative pressure relief

• Has positive pressure valve, negative pressure valve and reservoir bag
• Used with ACTIVE disposal systems
  
  • vacuum control adjusted so reservoir bag not overdistended or deflated
• Gas vented to atmosphere if pressure exceeds +5 cm h2o -
• RA entrained if less tha -0.5 cmh2o
  
  • Back up negative pressure relief vavle opens at -1.8 if first becomes occluded

Question 13

What are the components of the positive pressure relief closed interface?

Answer 13

Only positive pressure valve

No reservoir,

no vacuum

Question 14

What are the components of the positive and negative pressure relief closed interface?

Answer 14

Positive pressure relief valve Negative pressure relief valve Reservoir bag NEED VACUUM

Question 15

Describe the gas disposal tubing

Answer 15

• Connect scavenging interface to disposal assembly
• Different size and color than breathing system
• Passive systme hose needs to be short and wide
• Tubing needs to run overhead to prevent obstruction and kinking
• If connected to active gas disposal system, need DISS connector

Question 16

Describe the gas disposal assembly

Answer 16

• Consists of components used to remove waste gases from OR 2 types
  
  • Active- produces negative pressure in disposal tubing, needs negative pressure relief
  • Passive- pressure is raised above atmospheric by patient exhaling, manual squeezing of reservoir bag, or ventilator (needs positive pressure)

Question 17

Describe the passive system along with advantages and disadvantages.

Answer 17

Waste gas flows outside building via: open window pipe passing through wall extractor fan

Advantages:

• Inexpensive set up
• simple to operate

Disadvantage:

• impractical in some buildings

Question 18

Describe the active system

Answer 18

System connect exhaust of breathing system to hospital vacuum system via an interface controlled by needle valve Advantage:

• Convenient for large hospitals where many machines used in diff locations

Disadvantage:

• Vacuum system and pipework major expense
• Needle valve may need continual adjustment

Question 19

Describe the scavenging system check

Answer 19

• Ensure proper connection bw scavenging systme and both APL valve and ventilator relief valve, and waste gas vacuum
• Fully open APL valve and occlude Y piece
• With min o2 flow, allow scavenger reservoir bag to collapse completely and verify pressure gauge reads zero
• With o2 flush activated, allow scavenger reservoir bag to distend fully, verify pressure reads less than 10 cmh2o

Question 20

What is the gold standard to determine if patient is ventilated

Answer 20

ETCO2

Question 21

What is the purpose of capnography?

Answer 21

1. Ventilator settings- avoid too much or little ventilation
2. Placement- confirm placement in trachea instead of esophagus
3. Aerobic metabolism- MH
4. Circulatory abnormalities- PE, hypotension, occult hemorrhage, cardiac arrest
5. Exchange air/o2- without airway, helps make sure pt exchanging air
6. Detect circuit disconnections

VPACED

Question 22

What are the clinical uses of capnography?

Answer 22

• Provide estimate of PaCO2 (PaCO2 >PETCO2)
  
  • 2-5 mmHg under GA
• Evaluation of dead space. V/Qmismatch= Gradient increase= dead space increase

Question 23

What are methods of measuring CO2 in expired gas?

Answer 23

Colorimetric

Infrared Absorption Spectrophotometry

Question 24

What is colorimetric measuring of CO2?

Answer 24

Rapid assessment of CO2 presence Metacresol Purple impregnanted paper

• changes color when co2 combines with H2O

Question 25

What is infrared absorption spectrophotometry

Answer 25

• Most common analyzer
• Determination of the proportion of its contents
• Each gas in mixture absorbs infrared radiation at diff wavelengths
• Amt CO2 measured by detecting its absorbance at specific wavelenghts and filtering absorbance related to to other gases

Question 26

What are two types of infrared absoprtion spectrophotometry?

Answer 26

Mainstream

Sidestream

Question 27

Describe mainstream capnography.

Answer 27

• Flow through
• Heated infrared measuring device in circuit
• has to be heated to avoid effects of h2o condensation
• Sensor window must be clear of mucous
• Less time delay
• Weight- kinks ETT and increase dead space
  
  • less of issue with new tech

Question 28

Describe Sidestream Capnography.

Answer 28

• Aspirates fixed amt gas/minute (30-500mL/minute)
  
  • may need to consider with ped sampling
• Transport expired gas to sampling cell via tubing -
• Best location near ETT
• Time delay
• Potential disconnect source
• Water vapor- condensation- traps/filters used

Question 29

Describe phase 1 in capnography

Answer 29

• inspiratory baseline
• no co2 reading
• inspiration and first part expiration
• dead space exhaled= should be 0
• if not co2 scrubber is exhausted or pt rebreathing

Question 30

Describe phase II in capnography

Answer 30

• expiratory upstroke
• sharp upstroke represents rising co2 level in sample leaving evently
• Slope determined by evenness of alveolar emptying
• Mixture of dead space and alveolar gas
• Asthma attack more slanted and may lose it all together in severe bronchospastic episode

Question 31

Describe phase III Capnogrpahy

Answer 31

• Plateau region of capnograph corresponds to pco2 in alveolar ventilation
• Constant or slight upstroke
• LONGEST phase
• Alveolar gas sampled
• Peak at end of plateau is where reading taken
• Normal 30-40
  
  • Adjust tidal volume to reach taget
• Reflection of PACO2 and Paco2

Question 32

Describe phase IV capnogrpahy

Answer 32

Sharp downstroke of PCO2 occurs as fresh inspired gas moves past sampling site and washes out remaining CO2

• Beginning of inspiration
• CO2 concentration rapid delcine to inspired value

Question 33

What are 5 characteristics to the ETCO2 curve?

Answer 33

1. Frequency
2. RHythm
3. Height
4. Basline
5. Shape

Question 34

Answer 34

Normal capnogram

Question 35

Answer 35

Normal capnograph during spontaneous breathing

Question 36

Answer 36

Increased upslope of phase III, may occur durign bronchospasm, (asthma, copd) or partially obstructed ETT or breathing circuit

Question 37

Answer 37

Cardiogenic oscillations at end of exhalation as flow decreases to 0 and beating heart causes emptying of diff lung regions and back and forth motion b/w exhaled and fresh gas

Question 38

Answer 38

Clefts during phase III that indicate spontaneous breathing efforts during controlled mechanical ventilation

Question 39

Answer 39

Esophageal intubation

Question 40

Answer 40

Rebreathing CO2. as may occur with faulty expiratory valve or exhausted absorber system. Inspired CO2 is consistenly>0

Question 41

Answer 41

Faulty inspiratory valve, resulting in a slower downslope, which extends into inhalation phase (IV) as co2 in the inspiratory limb is rebreathed

Question 42

Answer 42

2 peaks in phase III that suggest sequential emptying of 2 heterogenous compartments, may be seen in patient with SOLT

Question 43

Answer 43

Faulty Inspiratory Valve

Question 44

Answer 44

Sudden shortening of duration of phase III during controlled mechanical ventilation suggests abrupt onset of ruptured or leaking ETT cuff

Question 45

Answer 45

• Dual plateua in phase III suggests presence of leak in sidestream sample line
• Ealy portion of phase III abnormally low because of dilution of exhaled gas with ambient air
• Sharp increase in CO2 at end of phase III reflects diminished leak resulting form increased circuit pressure at onset of inspiration

Question 46

What are we looking to verify ETT placement?

Answer 46

Presence of stalbe CO2 waveform for >3 breahts indicated tracheal intubation

NEED to listen to BBS for placement within trachea

Question 47

What causes rising in CO2 when ventilation unchanged?

Answer 47

1. Malignant Hyperthermia
2. Release tourniquet
3. Bicarb administration
4. Insufflation of CO2 into periotneal cavity
5. Equipment defect (exp valve stuck, CO2 absorbent exhausted
6. Release aortic/major vessel clamp

MR. BIER- died because of high CO2

Question 48

What causes decrease in ETCO2?

Answer 48

1 is gradual

1. Hyperventilation
2. Arrest
3. Sampling error
4. V/Q mismatch
5. Increase PACO2-PETCO2
6. PE

4-6 is rapid change

HAS VIP

Question 49

What is the generic process for all carbon dioxide absorbers?

Answer 49

CO2 +H2O make Carbonic acid (H2CO3). OH of an alkali or alkaline earth metal neutralizes the acid (base neutralizes acid).

End product is water, carbonate, heat

Question 50

What were issues with classic absorbers?

Answer 50

• Couldn’t change during case because disturbs circle system integrity
• Common source of leaks

Question 51

What are are the benefits of modern CO2 absorbers?

Answer 51

Can change during case

much less issues with leaks

Question 52

What are the common absorbents?

Answer 52

• Baralyme
• Amsorb Plus (Calcium Hydroxide lime)
• Litholyme (Lithium hydroxide)
• Soda Lime (Sodium hydroxide lime)

BALS

Question 53

What are the compounds and percentages in soda lime?

Answer 53

• 0.2% Silica- hardness
• 1% Potassium hydroxide
• 4% Sodium Hydroxide
• 15% H2O
• 80% Calcium hyhdroxide

(0.2-looks like an S, KOH is the “kid” and has the next smallest amount, Naoh next, need a decent amount of water (15), CaOH always 80%)

Question 54

What are some characteristics of Soda Lime? What is it efficiency?

Answer 54

• Silica added for hardness to prevent dust
• Capable of absorinb 26 L co2/100g absorbent granules
• 1 lb CaOH absorbs 0.59 lb CO2
• Water is present as thin film on granule surface
• Moisture is essential. Reaction only takes place between ions that only exist in presence of water

Question 55

What is the generic principle of soda lime’s reaction, and what is the chemical reaction formula?

Answer 55

• Carbom dioxide combines with water to form carbonic acid. Carbonic acid reacts with hydroxide to form sodium (or potassium) carbonate. water and heat
  1. CO₂+ H₂O⇔ H₂CO₃
  2. H₂CO₃+ NaOH (KOH)⇔ Na₂CO₃ (K₂CO₃)+ 2H₂O + Heat
  3. Na₂CO₃ (K₂CO₃) + Ca(OH)₂(quick reaction) ⇔ CaCO₃ + 2NaOH (KOH) + heat

SOME CO₂ may react directly with Ca(OH)₂, but this reaciton is MUCh slower (CaCO3 + H2O+Heat)

Question 56

What are the percentages and components of Calcium hydroxide lime?

Answer 56

• AKA Amsorb plus
• 80%Ca Hydroxide
• 16% H2O
• 1-4% Calcium chloride
• Calcium sulfate and polyvinylpyrroldine added hardness
• Capable of 10L CO2/100g absorbent granlues
  
  • less efficient than Soda Lime

Question 57

What is the chemical reaction for Calcium hydroxide lime?

Answer 57

1. CO2+H2O ⇔ H2CO3
2. H2CO3 + Ca(OH)2⇔ CaCO3+ 2H2O+ Heat

Question 58

What does Baralyme consists of?

Answer 58

• 20% BaOH, 80% CaOH
• Small amounts NaOH KOH added

Question 59

What are some characteristics of baralyme?

Answer 59

Granules 4-8 mesh

No hardening agent needed

Slightly less efficient than soda lime, but less likely to dry out

No water

implicated in fires

Absorptive capacity similar to soda lime 26L of CO2/100grams granules

Question 60

What is the chemical reaction of barium hydroxide lime?

Answer 60

1. Ba(OH) + 2(8H₂O) +CO₂⇔ BaCO₃+ 9H₂O +Heat
2. 9 H₂o+ 9CO₂⇔9H₂CO₃
3. 9H₂CO₃+ 9Ca(OH)₂⇔9CaCO₃+18H₂O+Heat

Question 61

Litholyme components and percentages?

Answer 61

• 75% LiOH
• 12-19% H2O
• <3%lithium chloride

Question 62

Reaction of lithium hydroxide monohydrate?

Answer 62

2LiOH *H₂O +CO₂⇔LI₂CO₂+3H₂O- heat

Question 63

What is the efficiency of Litholyme

Answer 63

• 1 pound LiOH absorbs 0.91 lb co2

Question 64

Talk about the purpose of indicators in co2 absorber?

Answer 64

• Color conversion signals absorber exhaustion
• Color reverts back with rest (especially in NaOH containing formulations)
• Replace absorbent with 50-70% color change
• Ethyl violet-most-common- critical pH 10.3

Question 65

What are the characteristics of absorbent granules?

Answer 65

• 4-8 mesh (number openings/in in a sieve through whichparticales can make it through)
• Irregular shape- increased SA
• Small granules increase resistance
  
  • BUT they have more SA
• Need blend of large and small granules to minimize resistance with little sacrifice in absorbent capacity

Grapes vs Watermelons

Question 66

What is purpose of granule hardness and how is it tested?

Answer 66

• Excessive powder can cause channeling resistance and caking
• Soda lime- silica added to increase hardness
• Tested with steel ball bearings and screen pan
• %origianl remaining= hardness number
• Hardness number needs to be >75

Question 67

What causes channeling in absorber?

Answer 67

• Preferential passage of exhaled gas flow through absorber via pathways of low resistance
• Results from loosely packed granules
• Air space 48-55% of volume of canister (normal)
• Absorbent along channels may exhaust
• CO2 filter may not be visible through channels
• CO2 monitoring needs to be used
• Some manufacturers now use a polymer to bind the granules in pref-roemd channels to prevent channeling

Question 68

What can develop with sevoflurane in contact with absorbent molecules?

Answer 68

• CO2 granules degrade volatile anesthetics agents to some extent, especially sevoflurane
• When degraded by strong base in co2 absorbents (esp KOH and lesser extent NaOH), sevo forms compound A
  
  • has been shown to cause nephrotoxicity in rats
  • Does not appear to be issue with absorbents with no KOH/NaOH
• Therefore manufacturer recommneds not more than 2MACH hr at flow rates 1-2L/min
  
  • Most provider use 2 L FGF with sevo although practice not EBP.
    
    • new absorbents don’t form compound A
      *

Question 69

Why are you concerned if your absorbent dries out?

Answer 69

• Carbon monoxide accumulates in desiccated (dry) NaOH and KOH containing absorbents when not used for 24-48 hrs (i.e. soda lime, baralyme)
  
  • high flow through system for long time= drys it out
  • With dried out absorbent, slow reaction occurs with volatile agents and absorbents that produce CO
  • Result in critically high levels of CARBOXYHYMOGLOBIN exposed patients
• Desflurance is associated with highest accumulation of CO

Question 70

What are anesthesia safety’s fondation recommendation on safe use of carbon dioxide absorbents?

Answer 70

• OCULAR
• Off- all gas flows off
• Color change- change when color change indicates exhaustion
• Uncertain of state of hydration
• Low flows preserve humidity in granules
• All absorbent- change
• Regularly

Question 71

When does the gas flow go through CO2 absorber?

Answer 71

Inhalation

Question 72

What is pathway of gas in absorber?

Answer 72

• Gases go from rebreathing bag
• down center absorber
• up through common fresh gas inlet
• out through inspiratory limb

Question 73

What is pathway of gases during exhalation by the CO2 absorber?

Answer 73

• Gas flows through the mask, into rebreathing bag and out the APL valve
• Fresh gas continues to flow from common gas outlet at machine into common gas inlet at absorber

Question 74

What would happen is you put desflurane in regular virally bypass vaporizer?

Answer 74

Potential delivery of hypoxic mixture and massive overdose of anesthetic gases

Question 75

Obstruction of the scavenging systems transfer tubing can cause what?

Answer 75

Barotrauma and increased breathing circuit pressure

Question 76

Inadequate vacuum setting in an open scavenging system will cause…

Answer 76

Leaking of excess scavenged gases to the OR