Abstract
INTRODUCTION: Cerebrovascular reactivity imaging (CVR) is a diagnostic method for assessment of alterations in cerebral blood flow in response to a controlled vascular stimulus. The principal utility is the capacity to evaluate the cerebrovascular reserve, thereby elucidating autoregulatory functioning. In CVR, CO(2) gas challenge is the most prevalent method, which elicits a vascular response by alterations in inspired CO(2) concentrations. While several systems have been proposed in the literature, only a limited number have been devised to operate in tandem with mechanical ventilation, thus constraining the majority CVR investigations to spontaneously breathing individuals. METHODS: We have developed a new method, denoted Additional CO(2), designed to enable CO(2) challenge in ventilators. The central idea is the introduction of an additional flow of highly concentrated CO(2) into the respiratory circuit, as opposed to administration of the entire gas mixture from a reservoir. By monitoring the main respiratory gas flow emanating from the ventilator, the CO(2) concentration in the inspired gas can be manipulated by adjusting the proportion of additional CO(2). We evaluated the efficacy of this approach in (1) a ventilator coupled with a test lung and (2) in spontaneously breathing healthy subjects. The method was evaluated by assessment of the precision in attaining target inspired CO(2) levels and examination of its performance within a magnetic resonance imaging environment. RESULTS AND DISCUSSION: Our investigations revealed that the Additional CO(2) method consistently achieved a high degree of accuracy in reaching target inspired CO(2) levels in both mechanical ventilation and spontaneous breathing. We anticipate that these findings will lay the groundwork for a broader implementation of CVR assessments in mechanically ventilated patients.