key: cord-0076206-se84paxw
authors: Thakur, Nagarjuna; Ramidi, Aamuktha Malyadha; Gopinath, R.; Srinivas, M
title: Indigenous adaptor for high flow nasal oxygen delivery
date: 2022-02-24
journal: Indian J Anaesth
DOI: 10.4103/ija.ija_812_21
sha: a813ed89c4f0f24dfde27e7f53ec9d33266a4553
doc_id: 76206
cord_uid: se84paxw

nan

High flow nasal cannula (HFNC) is a relatively newer non-invasive ventilation therapy that is well tolerated both in paediatric and adult care settings and was increasingly used during third wave of coronavirus disease-2019 (COVID-19). [1] Studies in newborn and children have suggested that HFNC may reduce the need for continuous positive airway pressure (CPAP) and invasive ventilation. [2] Initial flow rate recommendation begins with 2 litres/ kg/min. Flow rates can be increased to a maximum of 60 litres/min. [2, 3] HFNO acts by washout of nasopharyngeal dead space, increasing pulmonary compliance, functional residual capacity and airway pressure. [4] Management of COVID-19 patients entails administration of oxygen by various methods and the use of devices which might not be available in all locations. [5] Hence, there is a need for innovative products to ensure oxygen therapy that can be provided even at primary health centre level for better patient care. One such adaptation is the use of two sources of oxygen flow combined by a "Y-Connector" device. One limb of the device is connected to a Venturi adaptor for providing large total gas flows and the second limb is used for providing higher oxygen concentration.

The study was conducted in a medical college and super speciality hospital. The HFNO therapy was instituted by designing a simple prototype (Defence Research and Development Organisation, Hyderabad) of the mechanism described above [ Figure 1a ]. [6] The adaptor [ Figure 1b ] has two ports, both of which were connected to two sources of oxygen.

One end of the adaptor was connected to an oxygen source using a Venturi connector, while the side port was directly connected to oxygen tubing and patient end connected via a heat and moisture exchanger (HME ) filter to nasal prongs. Passive humidification could be provided if the oxygen tubings were connected to flow meters with humidifier bottles.

Peak flows: Mindray® flow pressure monitor device.

Side-stream analyser of Spacelab Blease Sirius (model: 700/900 series) Table 1a : Shows net peak flow and net FiO 2 delivered to the patient with the adaptor using various color-coded Venturi connectors. Standard flow rates as recommended for the Venturi device were used in oxygen tubing ' A' and varying flow rates from 6 to 15 litres with 3 litre increments were used in oxygen tubing 'B'. Highest peak flows delivered and FiO 2 achieved are marked and highlighted. 

The Surviving Sepsis Campaign guidelines for COVID-19 have suggested the benefit of HFNC device over non-invasive ventilation to obtain oxygen saturation (SpO 2 ) above 90%. [7] The commercially available standard HFNO oxygen therapy equipments allow warm and humidified oxygen with a maximum flow of 60 litres/min and positive end-expiratory pressure of up to 7.2 cm of water. Our indigenous adaptor is lightweight, cost-effective and easy to make. It might be useful as a rescue oxygen therapy in resource limited settings where commercial HFNO devices are not available, and this device can provide high peak flows in the current COVID-19 pandemic with the help of oxygen cylinders.

Multiple prototypes of adaptors with various inner to outer diameters ratios were tested for generation of maximum peak flows. The inner to outer diameter ratios of various adaptors used were 1:5.3, 1:1.47, 1:1.37, 1:1.22. Of all the prototypes, the inner to outer diameter ratio of 1:1.37 generated the maximum peak flows and FiO 2 .

With fixed flows through the Venturi, increasing the flow through the oxygen tubing, connected directly to the adaptor, did not yield higher peak flows but increased the FiO 2 by 2-3 times from the expected values of the Venturi adaptors. Whereas, by increasing the oxygen flow connected to the Venturi, peak flows were increased by 2-3 times and FiO 2 was increased only by 1.5-2 times.

This indigenous adaptor can only provide passive humidification when oxygen is supplied through flow meters with water-filled humidifier bottles. Absence of heating is the only limitation with the adaptor.

We conclude that variable combination of flow rates with passive humidification would be practical and useful in remote/resource limited settings. The adaptor, by providing high flows of oxygen can be used where standard HFNO machines are not available.

Acknowledgments: Prototype design and 3D printing Dr. John RozarioJegaraj, Scientist F, Head PE and IID, Financial support and sponsorship Nil.

There are no conflicts of interest. 

High-flow nasal oxygen therapy and noninvasive ventilation in the management of acute hypoxemic respiratory failure

High-flow nasal cannula for acute hypoxemic respiratory failure in patients with COVID-19: Systematic reviews of effectiveness and its risks of aerosolization, dispersion, and infection transmission

Airway devices in paediatric anaesthesia

High-flow nasal cannula: Mechanisms of action and adult and pediatric indications

Hyperbaric oxygen therapy: Can it be a novel supportive therapy in COVID-19?

Equipment for inhalation of oxygen and other gases

Surviving Sepsis Campaign: Guidelines on the management of critically ill adults with Coronavirus Disease 2019 (COVID-19)

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