Influence of Ambient Temperature and Minute Ventilation on Passive and Active Heat and Moisture Exchangers

Discussion

In this study, we have demonstrated on a hygrometric bench that ambient temperature and minute ventilation had negligible influence on the humidification performance of 2 passive hygroscopic and hydrophobic HMEs (Hygrobac and Hygrobac S) and one active HME (Humid-Heat). The active HME provided water content in the inspiratory gas from 4.2 to 5.6 mg H₂O/L higher than in the tested HMEs, depending on the conditions. In mechanically ventilated patients, the active HME provided high levels of humidity (from 38 to 42 mg H₂O/L). Even when tested with the active component turned off, the active HME still provided satisfactory water content to most of the patients.

It was previously shown that heated wire HH performance could be strongly influenced by ambient temperature. Due to their working principles, in the case of high ambient temperatures, water content of inspired humidity fell ∼20 mg H₂O/L with heated wire HH, well below the manufacturer's stated specifications, but with a partial correction when the compensation algorithm was activated.¹⁰ However, it must be noted that this compensation algorithm was not available in North America until very recently. In the present study we demonstrated that ambient temperature had minimal influence on 2 hydrophobic-hygroscopic HMEs and one active HME. With the tested devices, we have observed a slight increase in absolute humidity delivered when measured at the highest ambient temperature (28–30°C). However, the psychrometic method may be slightly influenced by ambient temperature, which could in part explain these results.¹³ The differences between high and low ambient temperatures was < 2 mg H₂O/L for all the tested devices, which may not be clinically relevant. Overall, the performance of passive and active HMEs remained stable whatever the tested conditions. We measured humidity in the inspiratory gases near 30 mg H₂O/L (Hygrobac S) or slightly above (Hygrobac), which is close to the values found in the literature^11,17 and in our previous studies with the same hygrometric method.^9,21 With the active HME, the delivered humidity was ∼35 mg H₂O/L in the bench study and close to 40 mg H₂O/L in the clinical study.

There is no previous study, to our knowledge, that assessed the impact of ambient temperature on active HME performance to compare with our data. One study evaluated the impact of this factor on a passive HME. Croci et al¹³ had demonstrated in a bench study using the psychrometric method that hydrophobic HMEs could be slightly influenced by ambient temperature. The differences were small, ∼2 mg H₂O/L, favoring 26°C of ambient temperature in comparison with 20°C. The authors concluded that the clinical impact was likely negligible.

Likewise, the minute ventilation did not influence the performance of the tested devices in this study, unlike the initial report by Martin et al.^11,19 In these studies, the HME used (BB2215, Pall) was less efficient than the ones we used in the present study and was only hydrophobic, whereas the HMEs used in our study were both hygroscopic and hydrophobic.²¹ In a subsequent study, Martin et al²³ also demonstrated that hygroscopic and hydrophobic HMEs maintained acceptable performance in patients with minute ventilation > 10 L/min. Therefore, the minute ventilation should no longer be considered a contraindication to using HMEs of the last generation, as previously stated.^2,20

Active HMEs were developed to improve the humidification performance of the HMEs.⁷ At that time hydrophobic HMEs had poor performance, leading to high rates of endotracheal tube occlusions.^11,14–18 Larsson et al⁸ evaluated the Humid-Heat device using the gravimetric method. They found humidification levels > 40 mg H₂O/L, but the water content of expiratory gases was 40.7 mg H₂O/L, which is higher than we used on our bench (35 mg H₂O/L). This difference in water content in the expiratory gases on these 2 models probably explains the discrepancy in the Humid-Heat performance. We based our simulation of the expiratory gases on the clinical data in the literature reporting measured expiratory humidity.^9,24 In our study, the Humid-Heat device delivered inspiratory water content of 34.5 mg H₂O/L on the bench and 37.5 mg H₂O/L in patients. This difference is likely related to the patient's temperature, leading to higher expiratory humidity and consequently higher inspiratory humidity.⁹ In our study there was no statistically significant correlation between the patient's core temperature and inspiratory temperature with the Humid-Heat. This is different to what has previously been reported with HMEs.⁹ In a previous study we evaluated the Humid-Heat and Hygrobac devices in the setting of hypothermia, and showed the influence of core temperature on the humidification performance of HMEs.⁹ Pelosi et al¹² evaluated the Hygrovent Gold active humidifier (Medisize) and the Hygrobac HME in a bench study, and demonstrated the absence of any impact of minute ventilation on these devices. They also noted reduced humidification performance with both passive and active HMEs in the case of simulated hypothermia.¹² Other active HMEs were tested and provided data in line with our results, with better hygrometric performance in comparison with the last generation of HMEs and with the possibility of maintaining adequate humidity when the active function is turned on or off.^25,26

It may be justified to seek systems that improve humidification performance with stable levels > 35 mg H₂O/L. Indeed, there are very seldom endotracheal tube occlusions when humidification devices deliver inspiratory water content of ∼30 mg H₂O/L.^3,21 However, more subtle and early markers demonstrate that optimal humidification is still not achieved with the current humidification devices. Moran et al⁴ compared the endotracheal tube resistance before and after utilization in 44 mechanically ventilated patients with gas humidified by HH or HME. They found in both groups a similar and clinically relevant increase in tube resistance by an average of 53%. Other authors found progressive reduction of endotracheal tube diameter with different humidification devices.^27–29 In this regard, active HMEs providing humidity near 40 mg H₂O/L may theoretically be interesting to consider, but there is currently no clinical demonstration of the superiority of delivering 40 versus 30 mg H₂O/L. We have demonstrated higher humidification performance with the Humid-Heat device than in the comparison HMEs in both a bench and a clinical study. The comparator HMEs chosen were among the best performing in a previous study of 48 different HMEs. However, active HMEs are more expensive and more complex to use than passive HMEs.²¹ When compared with previous studies, the Humid-Heat device outperformed HHs in the case of high ambient temperature,¹⁰ but important issues with existing passive HMEs (ie, dead space) are still present with active HMEs. Finally, due to the possible condensation in the small airways, there is a risk of overhumidification when inspiratory gases are > 44 mg H₂O/L,^30,31 or even below that level if core temperature is < 37°C.⁹ We do not have clinical experience with humidification devices that really provide ≥ 40 mg H₂O/L, such as the Humid-Heat device. Indeed, when considering independent evaluations, the best-performing HMEs provide a level of 30 mg H₂O/L or slightly above²¹ and heated wire HHs provide a level of 36 mg H₂O/L within optimal conditions of utilization.^10,32 The hygrometric levels reached with the maximal minute ventilation (30 L/min), approaching 44 mg H₂O/L, could eventually lead to overhumidification. For all of these reasons, the clinical indication of active HMEs remains unclear.

Our study provides data of clinical relevance as we have demonstrated the stable humidification performance of the tested devices (passive and active HMEs) when minute ventilation or ambient temperature vary, which are frequent clinical situations. Clinicians must be aware of the variability in performance of heated wire HHs during conditions leading to high temperatures in the humidification chamber (ie, high ambient temperature, sun on the humidifier or some turbine ventilators).¹⁰ In addition, clinicians must know the impact of the patient's core temperature on passive and active HMEs with reduced humidification performance seen in the case of hypothermia.^9,12

Our study has a number of limitations. First, the study design did not allow evaluation of the long-term impact of these humidification devices on important clinical outcomes such as tube resistance or endotracheal tube occlusions. It is not possible to conclude with the current data that higher humidification performance is better for patients. Second, there are differences of 3 mg H₂O/L in inspiratory humidity between the bench and the clinical evaluation. This discrepancy may be related to the patient's core temperature of 37.7°C in the clinical evaluation, while the bench delivers an expiratory humidity based on clinical measurements while patient's core temperature was 36.5°C.^9,33 One degree of difference, may account for a difference of 2 mg H₂O/L for a saturated gas, which may in part explain the difference between the bench and the clinical evaluation. Finally, in our study, there was no evaluation of the clinical tolerance with prolonged use of systems that deliver humidity > 40 mg H₂O/L. Clinicians should be cautious as there is limited clinical experience with such conditions of humidification, which could lead to increased secretions and micro-atelectasis, as has been described in animals.^34,35

In conclusion, the humidification performance of passive, performing, hygroscopic and hydrophobic HMEs, and of active HMEs is not influenced by minute ventilation in the conditions tested in the present study, and ambient temperature has only a negligible influence. These systems are stable over a range of tested external conditions, and there is no reason to avoid their use in the case of high ambient temperature or in the case of high minute ventilation.² Clinicians should know the working principles of the humidification devices and must be aware of the influence of a patient's temperature on these devices, with reduced humidity delivered to the patients in the case of hypothermia.^9,12 Heated wire HHs are influenced by external factors (especially by high ambient temperature)¹⁰ but not by the patient's temperature.⁹ These influences should be known by the clinicians, and new devices with limited influence should be developed to optimize humidification strategies. Among alternative humidification devices, the active HME evaluated in this study demonstrated very high levels of humidification, but these systems share with HME the problems related to dead space^36–38 and are more complex to use. To date, there are no clinical data to recommend the use of active HMEs.