Circulation 75,648 • Volume 20, No. 2 • Summer 2005   Issue PDF

Descending Bellows Drives Question

David A. Ciochetty, MD; Abe Abramovich

We are currently evaluating new anesthesia machines for purchase. One of the models is a 2005 Datascope Anestar model. It has a hanging bellows.

The company states that the hanging bellows is no longer a concern. The uncoupling of the fresh gas flow means that an increase in fresh gas flow will NOT increase the tidal volume.

Do you have any resources, evaluations, or comments about the hanging bellows on the new machines? Dräger and Datex-Ohmeda do not have this type of bellows.

David A. Ciochetty, MD
Director, Anesthesia Department
Passavant Area Hospital
Jacksonville, IL

 

Response:

Dear Dr. Ciochetty,

Datascope appreciates the opportunity to respond to your inquiry about descending bellows and their relationship to a fresh-gas decoupled anesthesia circuit. However, before I get into the technical description of the Anestar’s circuit, I would like to unequivocally state that any modern anesthesia machine, marketed in the U.S. today, including the Anestar, is safe regardless of which ventilation technology is being employed. Information to the contrary may be outdated or intended to mislead.

As cost-effective sensor technology and embedded software have been integrated into anesthesia machines over the recent past, clinicians have benefited from new functionality unattained in previous generations of anesthesia delivery equipment. More importantly, such technology adds and automates an increased level of vigilance, with the ultimate benefit of increasing patient safety. Similarly, I am reminded of how driver safety is improved in a modern automobile through accepted invisible features such as ABS and traction control. All anesthesia systems on the market today control the fresh gas flow within the breathing cycle to achieve constant tidal volume delivery. In part, they depend on their alarm technology and other monitoring, such as capnography, to alert the user in case of disconnects or leaks.

Besides accepted visual indications of disconnects and leaks, manufacturers nowadays include additional alarms to appropriately alert the user. Several national and international standards have been developed to increase the safety and reliability of such indications.
Datascope’s Anestar has alarms which specifically indicate the following conditions:

  • Breathing circuit disconnect
  • Peak pressure below minimum pressure alarm
  • Tidal volume lower than VTmin
  • Minute volume below alarm limit
  • Ambient air intake: check fresh gas setting.

These alarms are in addition to a graphic, breath-by-breath, display of the pressure waveform.

Besides the electronic vigilance, in the case of a fresh-gas decoupled system, the physical/visual indication has shifted from the bellows to the reservoir (breathing) bag, which is always in the circuit. During normal operation, the bag has a full appearance and appears to pulsate, inflating slightly during inspiration and returning to normal volume during expiration. But, in case of a disconnect, or a major leak, the bag will deflate after a few breaths, simulating the behavior of ascending bellows.

If the leak is less than the fresh gas flow, the bag (reservoir) will supplement the fresh gas flow, while continuing to ventilate the patient and the bag will appear to pulsate more deeply. Since, indirectly, leaks are an implied topic of this discussion, I would like to point out that the Anestar breathing circuit, including the ventilator, absorber, valves, and sensors, are implemented in a module within a single aluminum block virtually eliminating the possibility of internal system leaks. Furthermore, the breathing module is warmed to 35°C to prevent condensation from occurring within the breathing circuit and the bellows.

At this point, I would like to provide a brief description of the operation of the Anestar’s fresh gas decoupling breathing circuit. Simply stated, a fresh gas decoupled anesthesia circuit delivers the set tidal volume to the patient independently of the fresh gas setting. We believe that the accurate delivery of set tidal volume is clinically important, especially when ventilating children.

In such a circuit, the bellows, reservoir bag, and decoupling valve facilitate a straightforward way to implement this technology without the need for external sensors and a feedback mechanism. In addition, this circuit’s configuration also facilitates a compliance compensation method, which corrects for compliance deviations external to the breathing module (e.g., patient’s breathing hoses).

Following the Anestar’s simplified schematic representation:

  1. When activated, the ventilator is immediately ready to deliver volume to the patient.
  2. During inspiration, the decoupling, PEEP, and bellows valves close while the ventilator controller generates a calculated flow of drive gas into the bellows housing. The bellows is displaced by the volume flowing into the bellows housing to create a positive pressure in the patient’s lungs and in the pathway between the decoupling and PEEP valves. The carbon dioxide absorber, APL valve, and reservoir bag are isolated from the patient circuit. During inspiration, fresh gas flows into the reservoir bag. Once the bag is filled, excess gas flows out the waste gas scavenger. Airway pressure is monitored inside the breathing module, and is additionally used to compensate for compliance.
  3. During expiration, based on the selected breath rate and I:E ratio, the decoupling, PEEP, and bellows valves open to allow gas to flow. At that time, the ventilator controller stops the flow of drive gas to the bellows housing. When these valves open, exhaled gas flows back through the one-way expiratory valve and carbon dioxide absorber. Based on the fresh gas flow rate, a portion of the exhaled gas flows out the APL and a portion is re-circulated. During exhalation, fresh gas flows through the open decoupling valve to refill the bellows, as the drive gas volume in the bellows housing is vented through the open bellows valve. As the bellows falls, gas is sourced from the fresh gas inlet first, which is the path of least resistance. The next source of gas is the gas returning from the absorber, and only if there is an interruption in the fresh gas source is gas drawn from the bag. The gas flow priority scheme, described above, is facilitated by the design of the Anestar’s breathing module. Exhaled volume is measured by a hot wire sensor located inside the breathing module, near the expiratory valve.

In summary, Dr. Ciochetty, the descending bellows is an essential part of the Anestar’s safe, state-of-the-art, reliable, and cost effective anesthesia circuit.

Fresh gas decoupling keeps complexity to a minimum and offers the clinical advantage of maintaining the set tidal volume independently of the fresh gas flow.

Respectfully Submitted,

Abe Abramovich
Director, Anesthesia Systems Development
Datascope Corp., Patient Monitoring Division
Mahwah, NJ