The document discusses different types of breathing circuits used in anesthesia. It begins by describing the basic components and functions of a breathing circuit, which delivers oxygen and anesthetic gases to patients while removing carbon dioxide. Circuits are classified as open, semi-open, semi-closed, or closed based on how exhaust gases are handled. Several specific circuit types are then outlined in detail, including the Mapleson A, Bain, Ayres T-piece, and Jackson-Rees systems. Key features and uses of each system are provided. Semi-closed circuits are explained as using a carbon dioxide absorber to remove carbon dioxide from exhaled gases so they can be rebreathed, allowing for lower fresh gas flow rates than open systems
2. Anesthetic gas exits the anaesthesia machine (via the
common gas outlet) and then enters a breathing
circuit. The function of the circuit is to deliver oxygen
and anaesthetic gases to the patient and to eliminate
CO2.
3. Classification
This most basic classification of breathing systems
divides them into open, semi-open, semi-closed or
closed.
4. Ideal breathing circuit
Simple and safe to use
Delivers the right gas mixture
Allows all methods of ventilation in all age groups
Efficient
Pressure relief
Sturdy, small and light
Allows easy removal of waste gases
Easy to maintain with low running costs
5. Components
Fresh Gas connection
Patient connection
Adjustable Pressure Limiting (APL) Valve
Reservoir (Bag or Bellows)
Tubing
Waste gas connection
6. Open method
FGF
Reservoir bag X
APL valve X
Open is the old
fashioned method of
dropping ether or
chloroform over a
gauze or lint
9. Apl valve
The valve disc is held in place by a weak spring,
the tension on which can be adjusted by a screw
mechanism, thereby adjusting the pressure
required to open the valve.
10. Types of Semi- closed Circuit
Systems
Mapleson A or Magill System
Mapleson A or Lack System
Mapleson D or Bain System
Mapleson F or Ayres T Piece System
Mapleson F with APL Valve
Mapleson C Bagging System
11. What FGF’s are needed?
Mapleson Systems Uses FGF SV FGF IPPV
A Magill
Lack
Spontaneous
Gen
Anaesthesia
70-100
ml/kg/min
≈ 1X MV
Min 3 x MV
B Very
uncommon, not
in use today
C Resuscitation
Bagging
Min 15 lpm
D Bain Spontaneous
IPPV, Gen.
Anaes
150-200
ml/kg/min
70-100
ml/kg/min
E Ayres T Piece Very
uncommon, not
in use today
F Jackson Rees Paediatric
<25 Kg
2.5 – 3 x MV
Min 4 lpm
12. Mapleson A (Magill) System
The Mapleson A or Magill system is good for
spontaneous breathing patients, so the fresh gas flow
can be lower. However as the APL valve is close to
the patient, it is regarded by many as difficult to use.
1950’s
13.
14. Inspiration - The valve closes and the patient inspires fresh gas from the
reservoir tube. Fresh gas flushes the dead space gas toward the patient.
Expiration - The patient expires into the reservoir tube. Towards the end
of expiration, the bag fills and positive pressure opens the valve,
allowing expired gas to escape. The patient end of the tubing is filled
with dead space gas followed by the alveolar gas. This stream travels up
the tubing and meets the fresh gas flowing into the circuit. The pressure
in the circuit increases and forces the expiratory valve to open, allowing
the alveolar gas to escape.
Expiratory pause - Fresh gas washes the expired gas out of the
reservoir tube, filling it with fresh gas for the next inspiration.
15. Mapleson A (Magill) System
Spontaneous ventilation
Re breathing of alveolar gas can be prevented if
the fresh gas flow = patient's minute ventilation.
16. Mapleson A (Magill) System
The Mapleson A is inefficient during controlled
ventilation. Venting the gas in the circuit occurs
during the inspiratory phase, and the alveolar
gases are retained in the tubing during the
expiration phase. Hence, alveolar gas is
rebreathed before the the pressure in the system
increases sufficiently to force the expiratory valve
open.
A fresh gas flow of >20 L/minute is required to
prevent rebreathing during controlled ventilation.
17. Mapleson A (Lack) System
The Mapleson A or Lack system is a modification of
the Magill where the valve is moved to the machine
end of the system using another length of tubing. This
adds volume to the system and makes it rather heavy
at the patient end.
1976
18. Mapleson D (Bain)
The Mapleson D or Bain System is a co-axial system
where the fresh gas is delivered directly to the patient.
It requires very high fresh gas flows to prevent
rebreathing of CO2. It is very convenient to use, thus
is very popular especially for induction, in the UK!
1972
19. Mapleson D (Bain)
A tube carrying fresh gas (F) travels inside an outer reservoir tube (R)
to the endotracheal tube connector (P).
20. The Bain circuit is a modification of the Mapleson D system. It is a
co-axial system in which the fresh gas flows through a narrow
inner tube within the outer corrugated tubing.
Inspiration - The patient inspires fresh gas from the outer reservoir
tube.
Expiration - The patient expires into the reservoir tube. Although
fresh gas is still flowing into the system at this time, it is wasted,
as it is contaminated by expired gas.
Expiratory pause - Fresh gas from the inner tube washes the
expired gas out of the reservoir tube, filling it with fresh gas for the
next inspiration
21. As with other co-axial systems, if the inner tube becomes disconnected or
breaks, the entire breathing tube becomes dead space, leading to severe
alveolar hypoventilation.
This may be detected in systems fitted with a bag by closing the valve and
activating the oxygen quick-flush. If the inner tube is intact, the Venturi
effect of the rapidly moving stream of gas leaving the inner tube will suck
gas out of the bag and the bag will empty.
If the inner tube is damaged, the stream of gas will be directed into the
bag and it will fill.
22. Mapleson D (Bain)
Spontaneous ventilation
Normocarbia requires a fresh gas flow of 200-300 ml/kg.
Controlled ventilation
A fresh gas flow of only 70 ml/kg is required to produce
normocarbia.
24. Mapleson F (Jackson Rees
Modification)
The Mapleson F or
Jackson Rees modification
of the Ayres T Piece is a
basic system for use with
very small patients.
It is a big disadvantage
that you cannot remove
waste gases safely.
Ayres – 1937
JR - 1950
25. Mapleson F (Jackson
Rees Modification)
Advantages of T-piece
systems
Compact
Inexpensive
No valves
Minimal dead space
Minimal resistance to breathing
Economical for controlled
ventilation
Disadvantages
The bag may get twisted and
impede breathing
High gas flow requirement
Uses
Children under 20 kg weight
26. Mapleson C Bagging System
The Mapleson C is more
than an anaesthesia
system. It can be found all
over the hospital for use
as an emergency bagging
system for resuscitation or
manual ventilation using
oxygen, as well as being a
standard induction system
in some countries.
27. Semi Closed Circuit Anaesthesia
This type of General Anaesthesia is used mainly for
maintenance of anaesthesia following induction. It can
be used for induction of anaesthesia, but this is a
slower process.
It requires an absorber system containing a CO2
Absorbent to remove CO2 from the expired patient
gases, and a high degree level of patient monitoring,
especially respiratory gas monitoring to measure
levels of inspired and expired CO2 and the volatile
28. Circle systems were first used back in 1930
by Brian Sword in the USA
29. Semi Closed Anaesthesia Explained
Semi Closed Anaesthesia is where the
expired gases from the patient pass through a
canister in the breathing system which
contains a CO2 absorbent. This absorbent by
an exothermic chemical reaction removes the
CO2, so the patients expired gases can be
rebreathed. Because of this exothermic
chemical reaction, some warmth and humidity
30. Inspiration - Inspiration causes the expiratory valve to close, and gas
flows from the breathing bag to the patient via the inspiratory limb of the
circuit. Anaesthetic is taken up from the in-circuit vaporiser (VIC), if fitted.
Expiration - The inspiratory valve closes and gas flows into the breathing
bag via the expiratory limb. CO2 is absorbed by the soda lime canister.
Excess gas is vented when necessary via the pressure-relief valve.
31. Semi Closed Anaesthesia Explained
Because the patients expired gases are re circulated
(where the ‘circle’ comes from), this means that we do
not have to add so much fresh gas to the system like
an open system. So the fresh gas flow rate can be
reduced to low flow, i.e., 1 l/minute. If the flows were
as low as a few hundred cc’s of gas, equivalent to the
patients metabolic uptake of gases, this would be
closed circuit anaesthesia, or metabolic (basal) flow,
or minimal flow.