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Mapleson Breathing Circuit Made Easy

Anatomy of Mapleson Breathing Circuit

Basically, a mapleson breathing circuit consists of following parts:

1. Face mask (towards patient end)

2. Reservoir bag (towards operator end)

3. Corrugated tube (between face mask and reservoir bag)

4. Fresh gas flow (FGF) inlet (at variable position)

5. Expiratory valve or Adjustable Pressure Limiting (APL) valve (at variable position)

Identification of Different types of Mapleson circuit

Mapleson A (Magill’s System)

Lack’s system: Co-axial modification of Mapleson A with APL valve away from patient end, i.e. face mask.

Mapleson B and C

Mapleson D

Bain’s system: Co-axial modification of Mapleson D in which the FGF supply runs inside the corrugated tube through which the expired gases are eliminated.

Mapleson E (Ayre’s T piece)

Mapleson F (Jackson Ree’s Modification of Ayre’s T piece)

Physiology of Mapleson A

Spontaneous ventilation

1. During expiration:

2. During expiratory pause:

3. At the beginning of inspiration: Depending upon FGF, patient breathes in –

FGF can be set to alveolar volume (about 70-80% of minute volume).

Gases at the end of expiration – left (spontaneous ventilation) and right (controlled ventilation).

Controlled ventilation

During expiration:

During inspiration:

Physiology of Mapleson B and C

Since, the FGF inlet is near the patient end – during expiration, 1st part of expired gas, i.e. dead-space gas passes down the corrugated tubing, along with FGF and the tubing near patient end contains FGF and some alveolar gas.

As the valve is in patient end, a mixture of alveolar and fresh gas passes out via the APL valve.

During inspiration, a mixture of fresh gas and retained alveolar gas is breathed in.

Physiology of Mapleson D

APL valve in use of Mapleson D

Spontaneous ventilation

1. During expiration:

2. During expiratory pause:

3. During inspiration:

Controlled ventilation

The functional analysis is similar in both spontaneous and controlled ventilation. Hence this system can be used safely during both spontaneous and controlled ventilation. The system is slightly more efficient during controlled ventilation because of the control over the expiratory pause. When high FGF (> 2 times the minute volume) is used, there is no rebreathing and the minute ventilation determines the arterial CO2 levels.

Mapleson E and F physiology

Due to absence of APL valve, the resistance in the system is lower compared to other systems and are preferred in pediatric patients for both the spontaneous and controlled ventilation. In Mapleson F or Jackson Ree’s circuit APL valve are replaced with open ended reservoir bag. Functionally, they are similar to Mapleson D.

Factors playing role in Rebreathing

Higher the Free gas flow (FGF), more efficient is the flushing of alveolar gas.

Longer the expiratory pause, more FGF is available, decreasing the rebreathing.

Higher the tidal volume, higher the alveolar gas enter corrugated tubing, increasing the rebreathing.

Aid for Viva-voce and Summary

  1. Fresh gas flow (FGF) inlet near reservoir bag = Mapleson A
  2. FGF inlet and APL valve near face mask = Mapleson B
  3. No corrugated tubing = Mapleson C
  4. APL valve near reservoir bag =Mapleson D
  5. No APL valve and reservoir bag = Mapleson E
  6. Open ended reservoir bag but No APL valve = Mapleson F
  7. Efficiency in Spontaneous ventilation: A>DFE>CB (Mnemonic: A Dog Can’t Bite)
  8. Efficiency in Controlled ventilation: DFE>BC>A
  9. Mapleson D is effective for both the controlled and spontaneous ventilation.
  10. Mapleson C is used in recovery rooms because they are small and light weight (no corrugated tubing).
  11. Jackson Ree’s circuit is used for both the spontaneous and controlled ventilation in pediatric patients.

 

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