The circulator concept

Bymixer system can measure O2 uptake and CO2 elimination in the anesthesia circle circuit

BACKGROUND

The ability to measure carbon dioxide elimination (Vco(2)), oxygen uptake (Vo(2)), and R (respiratory exchange ratio, Vco(2)/Vo(2)) during anesthesia may help the non-invasive detection of critical events (e.g., abrupt decrease in cardiac output) and metabolic upset (e.g., onset of anaerobic metabolism).

METHODS

We have developed a new clinical bymixer (inline mixing chamber) that can measure mixed inspired and expired gas fractions in the anesthesia circle circuit. The addition of a standard anesthesia gas analyzer and flowmeter, and a new airway temperature and humidity sensor, allow determinations of Vco(2) and Vo(2) at the airway opening of the circle circuit. Over a range of tidal volume and frequency, Vco(2) and Vo(2) were compared to reference values generated by the combustion of metered liquid ethanol in a new metabolic lung simulator.

RESULTS

By linear regression, bymixer-flow measurements of Vco(2) (slope = 1.02, Y-intercept = -5.31, coefficient of determination, R(2) = 0.998) and Vo(2) (slope = 1.05, Y-intercept = -4.34, R(2) = 0.993) correlated closely to the reference values generated by the metabolic lung simulator. Limits of agreement analysis generated percent errors (mean +/- 1.96 SD) of -1.2 +/- 7.2% for Vco(2) and 2.5 +/- 9.8% for Vo(2).

CONCLUSIONS

The new clinical bymixer is compact, lightweight, disposable, inexpensive, and has a fast and adjustable response time (time constant about 14 sec). Anesthesia circle circuit integrity is maintained. Bymixer-flow measurements of Vco(2) and Vo(2) are accurate and may add to clinical monitoring under anesthesia and surgery.

Closed carbon dioxide filtration revisited

There are compelling reasons why the closed carbon dioxide filtration method for inhalation anaesthesia deserves serious reconsideration. Use of the closed absorption system today can provide all the benefits recognised by those who introduced it seventy to eighty years ago. A most important benefit is the increased opportunity of learning afforded the user, which leads either neophyte or senior clinician to improvement of both concept and clinical skills. The current resurgence of interest is fully appropriate for all physicians who aspire to be true specialists in the care of patients during clinical anaesthesia.

Closed system with agent-specific vaporizers and nitrous oxide

Through judicious use of nitrous oxide the closed system can be quite effectively used with currently available equipment including both agent-specific direct-reading percentage vaporizers and suitable devices for the measurement of end-tidal concentrations of oxygen, carbon dioxide and anaesthetic agents. It is only necessary to think in terms of required volumes of fresh gases and vapours added to the system as well as the appropriate concentrations of oxygen and anaesthetic in the respired mixture. When used as described the inspired concentration of nitrous oxide in the closed system should never exceed 50% (usually about 40%). Therefore nitrous oxide will not pose the threat of hypoxaemia unless misused. Experience in teaching this method during the previous decade supports a belief that learning the use of a truly closed circle absorption anaesthesia system is fundamentally important to the development of clinical skills and also facilitates understanding of basic concepts related to respiratory physiology and the uptake and distribution of inhalation anaesthetics. It follows that students and residents should be introduced to this method in the early weeks of their learning experience.

The "D circle": closed-circuit operation of the Bain circuit

A method of converting a Mapleson D (Bain) circuit to closed-circuit operation is presented, utilizing a laboratory air pump and a Waters carbon dioxide absorber canister to recirculate exhaled gas. The elimination of carbon dioxide from the circuit was studied and found to be adequate. The circuit would allow the use of low fresh gas flows for the maintenance of anaesthesia without the danger of carbon dioxide rebreathing. We suggest that such a circuit could provide appropriate conditions of gas humidity and temperature for endotracheal anaesthesia, while realizing the advantage of a circulator in mask anaesthesia is possible. Further design considerations for a "D circle" breathing system for clinical use are discussed.