Oxygen therapy is a widely used treat- ment modality which, when administered correctly, can be life-saving. Published 
data have demonstrated that a large proportion of 
doctors and nurses have been unable to accurately 
follow the proper methods for administration of 
oxygen.1,2 Administration of oxygen through cold 
bubble humidifiers is part of the generic approach to 
acute respiratory failure due to a whole host of causes, 
especially in poorly resourced health systems.3,4 This 
article attempts to systematically challenge the age-old 
practice of cold bubble humidification by questioning 
the norm of prescribing ‘moist oxygen’ to all patients 
irrespective of oxygen flow rate. To establish our 
views, we have elucidated the concepts of low-flow 
and high-flow oxygen therapy, the physiology and 
physics of humidification and the risks of infections 
associated with cold bubble humidifiers. Finally, we 
have concluded that cold bubble humidifiers are 
unable to meet the physiological needs of the upper 
airway, thereby rendering them far less effective when 
compared to heated humidifiers. 

Low Flow and High Flow 
Oxygen

Oxygen delivery systems have always remained a 
critical component of patient care both in hospitals or 
otherwise.3 Devices for the delivery of medical oxygen 
can be broadly categorised on the basis of oxygen 
flow rates into high-flow and low-flow devices. The 
required flow rate is determined for individual patients 
on the basis of their peak inspiratory flow rate, which 
in turn is dependent on each patient’s pre-existing 
respiratory ailment.3 

Low-flow oxygen therapy devices are also known 
as variable performance devices.4 These devices 
deliver a variable fractional inspired concentration of 
oxygen (FiO2) according to the variations in minute 
ventilation (variations in tidal volume, respiratory rate 
and inspiratory flow) of a patient. Although the device 
delivers 100% oxygen to the upper airway, the final 

FiO2 delivered is the result of mixing variable amounts 
of inhaled room air.5 Severely breathless adult patients 
often generate inspiratory flows of greater than 40–60 
L/min. As the low flow devices usually supply oxygen 
at flow rates (maximum 15 L/min in India) lower 
than the dyspnoeic patient’s inspiratory demand, a 
variable amount of room air is required to achieve the 
required flow.3,4 Therefore, FiO2 in inspired air varies 
substantially. Examples of commonly used low-flow or 
variable performance oxygen therapy devices are nasal 
cannulae, simple face masks and partial rebreathing 
and non-rebreathing reservoir masks.5

High-flow or fixed performance devices such as 
air entrainment masks, large volume nebulisers and 
high-flow nasal cannulae (HFNC), provide oxygen at 
flow rates adequate enough to meet the inspiratory 
demands of the patient.5,6 These devices blend 100% 
oxygen with room air to produce a final inspired gas 
with the desired FiO2. They also provide an inspiratory 
flow high enough to exceed any tidal volume, 
respiratory rate and inspiratory flow a breathless 
patient might usually generate, thereby preventing 
dilution of FiO2 by entrained room air. Therefore, high-
flow, fixed-performance devices deliver a predictable 
FiO2. HFNC are always used with heated humidifiers. 
The delivered concentration and flow of oxygen affect 
the final FiO2 and they can be controlled independently 
in some devices. However, direct caregivers should be 
cautious that even with these devices, the FiO2 can 
be reduced if the inspiratory flow of an occasionally 
severe dyspnoeic patient exceeds the device’s total 
flow output. With the emergence of the COVID-19 
pandemic, the potential of HFNC as an alternative to 
standard oxygen therapy and non-invasive ventilation 
(NIV) has been revisited with special interest across 
the globe. Guy et al. in a monocentric study concluded 
that HFNC was effective in managing COVID-19 
patients in an intensive care unit setting.7 A study of 
moderate to severe COVID-19 patients by Geng et al. 
suggested that the administration of HFNC reduced 
the rate of intubation and improved the clinical 
outcome in type 1 acute respiratory failure.8

Departments of 1Critical Care Medicine and 2Internal Medicine, RG Kar Medical College and Hospital, Kolkata, India
*Corresponding Author’s e-mail: chandraatanu123@gmail.com

 This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

Cold Bubble Humidification of Oxygen
Old habits die hard

Sugata Dasgupta,1 Shrestha Ghosh,2 *Atanu Chandra2

EDITORIAL

Sultan Qaboos University Med J, August 2022, Vol. 22, Iss. 3, pp. 309–313, Epub. 25 Aug 22
Submitted 2 Nov 21
Revision Req. 21 Nov 21; Revision Recd. 30 Nov 21
Accepted 9 Dec 21 https://doi.org/10.18295/squmj.1.2022.002

https://creativecommons.org/licenses/by-nd/4.0/


Cold Bubble Humidification of Oxygen 
Old habits die hard

310 | SQU Medical Journal, August 2022, Volume 22, Issue 3

P h y s i o l o g i c a l  H u m i d i f i c a t i o n : 
Absolute and relative humidity

The importance of the upper airway is often 
understated. However, it holds special significance 
with regard to understanding the processes behind the 
physiological humidification of inspired air. Besides 
the upper airway, the trachea provides a counter 
current mechanism for heat and moisture exchange 
during breathing and hence plays an important role in 
heating and humidifying inspired gas. 

Understanding the concept of humidity and 
the ways to measure it is beneficial in a discussion 
pertaining to the physiology of humidification of 
inspired gas.4 Humidity is quantified in two ways; 
Absolute humidity (expressed in g/m3) defined as 
the mass of water vapour present per unit volume of 
gas at any given temperature and pressure.9 Relative 
humidity (expressed as a percentage) is a comparative 
measurement describing the ratio between the mass 
of water vapour present in a given volume of air to the 
mass of water vapour required to completely saturate 
said volume of air at a particular temperature.4

The nose is the site of maximal heat and moisture 
exchange. A gradient of heat and absolute humidity 
is achieved down the upper airway.10 The normal 
temperature, relative humidity and absolute humidity 
of inspired gas at the airway opening are about 22°C, 
50% and 10 g/m3, respectively. After normal heating 
and humidification mechanisms in the intact upper 
respiratory tract, these values reach 29–32°C, 95% and 
28–34 g/m3 in the oropharynx and 32–36°C, 100% 
and 34–40 g/m3 in the trachea. On reaching the lungs, 
the inspired gas is fully saturated with water vapour 
at body temperature (37°C, 100% relative humidity, 
44 g/m3 absolute humidity).11 The point at which this 
occurs is called the isothermic saturation boundary 
(ISB) which is approximately 5 cm distal to the carina 
at the level of the third generation airways.4

Nasal mucosa is kept warm and moist by 
secretions from goblet cells and mucous glands such 
that when inhaled air passes through the path created 
between the turbinates, incoming air is warmed by 
convection. Liquid moisture from the epithelial lining 
evaporates by utilising latent heat of vaporisation to 
add to the humidity of inhaled air. Heat and moisture 
exchange is crucial to maintaining mucociliary 
function as the ciliary motility is drastically reduced, 
airway irritation is increased and pulmonary secretions 
become viscid and inspissated when exposed to cold, 
dry air.12 Respiratory heat loss occurs during exhalation 
as latent heat is released when water vapour from 
saturated exhaled air condenses in the upper airways. 

Thus, the airways are prepared for another cycle of 
heating and humidification of inspired air. 

The Physics of Humidification

Humidifiers form an important part of oxygen 
delivery systems. A variety of devices are available to 
achieve ideal humidity levels that are as close to the 
physiological requirement as possible. Based on their 
mechanism of action, humidifiers are divided into 
active and passive types.9 Active humidifiers such as 
bubble and pass-over humidifiers add water or heat or 
both to the inspired gas. Passive humidifiers such as 
heat and moister exchangers (HME) for example, use 
exhaled heat and moisture to humidify inspired gas. A 
nebulizer produces an aerosol (a suspension of water 
particles in gas) for humidification.

Bubble humidifiers are one of the most common 
humidifiers used in developing countries such as 
India.13 These are water containers in which gas is 
forced to escape through a tube placed at the bottom.14 
The gas bubbles collect moisture as they move towards 
the water surface and pass through an outlet connected 
to an oxygen delivery device. A number of factors 
govern the amount of water vapour gained through 
this process. Lower flow rates allow longer contact 
time between the gas and water thereby increasing 
humidity. The higher is the flow through a bubble 
humidifier, the lower the water vapour content and 
temperature of the gas leaving the device. Flow rates 
of more than 10 L/min usually result in decreased 
contact time and inability to achieve required absolute 
humidity.13 The absence of a diffuser also lowers 
humidity. Diffusers break larger gas bubbles into 
smaller ones, increasing the surface area thus enabling 
greater gas-liquid interaction. Moreover, a heat source 
provides the latent heat of vaporisation required to 
maximize the humidification of gas.

More often than not, especially in resource-
limited setups, there is an absence of a heat source. 
The resultant use of cold bubble humidification 
generates an absolute humidity of only 10–20 g/m3 at 
standard room temperature against the physiological 
requirements of at least 34 g/m3 in trachea and 44 g/
m3 below carina at the ISB.13 A comparison of various 
humidifiers shows that while cold bubble humidifiers 
and HMEs drastically fail to provide 100% saturation 
at 37°C and heated water baths just meet the requisite 
levels, heated nebulisers based on the Bernoulli-effect 
and ultrasonic nebulisers more than surpass the 
mark.13



Sugata Dasgupta, Shrestha Ghosh and Atanu Chandra

Editorial | 311

Infections Associated with Cold 
Bubble Humidifiers

Respiratory tract infections are the most common type 
of healthcare-associated infections (HAI).15 Elderly, 
immunocompromised or critically ill subjects are 
particularly susceptible to the nosocomial infections 
caused by several bacteria and fungi. Equipment used 
for respiratory care such as nebulisers, ventilators 
and humidifiers may act as potential vehicles for 
transmission of those organisms, though their exact 
role in the causation of HAI is still a matter of debate. 
Humidifiers may serve as a reservoir of several 
microorganisms as the fluids inside them may be 
contaminated by different bacteria and fungi. Some of 
the organisms may also multiply in the stagnant water. 
The organisms gain access to the host in two ways: 
either from the aerosolisation in the room or through 
direct delivery to the airways.16 Moreover, many gram-
positive and gram-negative bacteria can form biofilms 
over medical devices; some of the important organisms 
among them are Staphylococcus aureus, Enterococcus 
faecalis, coagulase negative Staphylococcus, Klebsiella 
pneumonia and Pseudomonas aeruginosa.17

La Fauci et al. conducted a study by collecting 
water samples from disposable and reusable oxygen 
humidifiers from different wards and processed 
them for microbial analysis.18 They found a very 
high rate of microbial contamination in samples 
from reusable oxygen humidifiers in comparison to 
the disposable ones. The contamination rate in the 
reusable oxygen humidifiers in emergency areas was 
more than 50% and the most relevant pathogens 
were Pseudomonas aeruginosa and Staphylococcus 
aureus. Another hospital-based study conducted by 
Jadhav et al. showed that colonisation rates of the 
oxygen humidifier chambers of portable cylinders 
and pipelines by bacteria and fungi were 75% and 87% 
respectively.16 Aspergillus Spp. was the most common 
among the fungal isolates. Among the gram negative 
bacteria, several multi-drug resistant organisms 
such as Klebseilla pneumonia, Pseudomonas spp., 
Acinetobacter spp. and Escherechia coli were isolated.

Recommendations 

Jadhav et al. demonstrated the importance of disinfection, 
documenting reduced colonisation rates of 15% and 
12% for fungi and bacteria, respectively, after maintenance 
of hand hygiene and disinfection of humidifier chambers 
with 70% ethanol.16 Overall, it is recommended that 
sterile water be used instead of tap water along with 
regular and thorough cleaning and changing of humid- 

ifiers to prevent microbial growth. However, with resources 
being stretched to a maximum, especially during the on-
going pandemic, meticulous implementation of such 
practices may prove to be difficult. Hence, revisiting the 
rationale behind routine usage of humidified oxygen 
over ‘dry’ (without usual cold bubble humidification) 
oxygen is reasonable. 

Non-humidified and non-heated air-oxygen 
mixtures can lead to increased airway resistance, 
dried up upper airway mucosa leading to reduced 
mucociliary clearance, airway mucosal inflammation 
and damage and an increase in the amount of energy 
expended by patients to warm and humidify the 
delivered gas.19 Cold bubble humidifiers are unable to 
add the necessary amount of humidification and heat 
needed to prevent the above mentioned complications. 
Over the years, several studies have validated that there 
is little difference in clinical outcomes and symptom 
severity between patient groups using humidified and 
non-humidified oxygen.20,21

The British Thoracic Society guidelines do not 
recommend routine humidification of oxygen when 
delivered under low flow (1–4 L/min) unless upper 
airways are bypassed, as in intubated or tracheotomised 
patients.22 Higher flows of oxygen (>4 L/min) can cause 
upper airway discomfort due to dryness, although most 
patients may be able to tolerate it. The maintenance 
of adequate hydration of all patients receiving supple- 
mental oxygen remains most essential. The guidelines 
also suggest administering normal saline nebulisation 
for liquefying viscid secretions, further negating the 
requirement of oxygen humidification.22

Furthermore, high-flow oxygen therapy, if needed, 
should be provided with heated humidifiers as opposed 
to cold bubble humidifiers which are highly ineffective. 
Studies by Santana et al. and Franchini et al. support 
that finding that cold bubble humidifiers fail to 
provide any additional humidity to nasal mucosa 
when compared to non-humidified oxygen therapy.23,24 
Humidification of inspired oxygen can only be 
considered in patients who complain of excessive nasal 
dryness associated discomfort. However, topical 
application of water-based lubricants can be a 
reasonable solution to this complaint.4 In published 
guidelines on oxygen therapy in paediatric patients, 
available evidence has not supported the use of heated 
or unheated humidification with low-flow oxygen 
delivery.25,26

Conclusion

Warren Buffet once said, ‘Chains of habit are too 
light to be felt until they are too heavy to be broken;’ 



Cold Bubble Humidification of Oxygen 
Old habits die hard

312 | SQU Medical Journal, August 2022, Volume 22, Issue 3

in this context, it would be essential to consider the 
dangers of continuing the common practice of cold 
bubble humidification. With the growing need for 
oxygen administration due to COVID-19 infection, 
the importance of heating and humidification with 
oxygen administration should be reaffirmed. However, 
the issue is universal and not associated only with the 
current pandemic. In light of better technology, cold 
water humidifiers have been rendered redundant as 
they are unable to provide the adequate humidification 
required by the respiratory tract. Moreover, evidence 
suggests that humidification is not mandatory in 
patients on oxygen therapy with any of the low-flow 
delivery devices, as described earlier. Furthermore, 
it is imperative that cold bubble humidifiers are 
acknowledged as a breeding ground of infections, 
especially in resource-stretched facilities due to 
difficulty in regular cleaning and maintenance. 
Since cold bubble humidifiers are evidently unable 
to humidify to the levels required, it appears that its 
usage should be abandoned as it offers no significant 
added advantage over room air and also increases the 
potential for infection risk. 

a u t h o r s’ c o n t r i b u t i o n s
SD and SG prepared the manuscript with adequate 
planning and execution. SD and AC contributed to 
the review of literature, critical revision of content and 
final approval of the manuscript. All authors agree to 
be accountable for all aspects of the work and ensure 
that questions related to the accuracy or integrity of 
any part of the work are appropriately investigated and 
resolved.

a c k n o w l e d g e m e n t

We are extremely grateful to Dr Farhad N. Kapadia, 
consultant physician and intensivist at Hinduja 
Hospital, Mumbai, India, for providing his valuable 
inputs on this topic.

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