Cost Analysis of Different Medical Oxygen Sources for a Healthcare Facility in India

Overview

Journal Indian J Anaesth

Specialty Anesthesiology

Date 2024 Apr 8

PMID 38586273

Authors

Varun Manhas

Mahipal Rawat

Yogesh S Kaurav

Sanjay Goyal

Sanjay Dhir

Kalyani Sangineni

Affiliations

Soon will be listed here.

Abstract

Background And Aims: Multiple sources of medical oxygen, namely liquid medical oxygen (LMO) tanks, pressure swing adsorption (PSA) plants, concentrators, and gaseous cylinders, are available at different healthcare facilities. These sources of oxygen have varying installation and operational costs. In low-resource settings, it is imperative to utilise these assets optimally. This study investigated the operational costs of multiple oxygen sources available at a healthcare facility.

Methods: A Microsoft (MS) Excel-based model was developed to analyse and compare the oxygen manufacturing costs (in ₹/m) using PSA plants and procurement costs (in ₹/m) of LMO and third-party vendor-refilled cylinders.

Results: The oxygen manufacturing costs for PSA plants of different capacities and running times on electricity and diesel generators (DGs) as a power source were calculated. This study highlights the cost-benefit of using PSA plants over LMO and third-party vendor-refilled cylinders as a source of oxygen. PSA plants are most economical when they are of higher capacity and used to their maximum capacity on electricity as the power source. On the contrary, they are most expensive when used on a DG set as a power source. Furthermore, this study provides evidence of PSA plants being more cost-effective for refilling cylinders using a booster compressor unit when compared to third-party vendor-cylinder refilling.

Conclusion: Given their cost-effectiveness and low third-party dependence, they should be utilised to their maximum capacity as medical oxygen sources at healthcare facilities.

Citing Articles

Reducing global inequities in medical oxygen access: the Lancet Global Health Commission on medical oxygen security.

Graham H, King C, Rahman A, Kitutu F, Greenslade L, Aqeel M Lancet Glob Health. 2025; 13(3):e528-e584.

PMID: 39978385 PMC: 11865010. DOI: 10.1016/S2214-109X(24)00496-0.

References

McAllister S, Thorn L, Boladuadua S, Gil M, Audas R, Edmonds T . Cost analysis and critical success factors of the use of oxygen concentrators versus cylinders in sub-divisional hospitals in Fiji. BMC Health Serv Res. 2021; 21(1):636. PMC: 8249838. DOI: 10.1186/s12913-021-06687-8. View

Balys M, Brodawka E, Korzeniewska A, Szczurowski J, Zarebska K . LCA and economic study on the local oxygen supply in Central Europe during the COVID-19 pandemic. Sci Total Environ. 2021; 786:147401. PMC: 8081744. DOI: 10.1016/j.scitotenv.2021.147401. View

Smith V, Changoor A, McDonald C, Barash D, Olayo B, Adudans S . A Comprehensive Approach to Medical Oxygen Ecosystem Building: An Implementation Case Study in Kenya, Rwanda, and Ethiopia. Glob Health Sci Pract. 2023; 10(6). PMC: 9771461. DOI: 10.9745/GHSP-D-21-00781. View

Duprez F, Michotte J, Cuvelier G, Legrand A, Mashayekhi S, Reychler G . Accuracy of Oxygen Flow Delivered by Compressed-Gas Cylinders in Hospital and Prehospital Emergency Care. Respir Care. 2017; 63(3):332-338. DOI: 10.4187/respcare.05657. View

Madaan N, Paul B, Guleria R . Meeting oxygen requirements of rural India: A self-contained solution. Indian J Public Health. 2021; 65(1):82-84. DOI: 10.4103/ijph.IJPH_1405_20. View