Solar Powered Oxygen Delivery

Phase 2

Completed

• Conditions: Hypoxemia; Pneumonia
• Interventions: Device: Solar powered oxygen; Device: Oxygen from cylinders

• Registration Number: NCT02100865
• Lead Sponsor: University of Alberta

Brief Summary

Globally, approximately 2.1 million children die of pneumonia each year. Most deaths occur in resource-poor settings in Africa and Asia. Oxygen (O2) therapy is essential to support life in these patients. Large gaps remain in the case management of children presenting to African hospitals with respiratory distress, including essential supportive therapies such as supplemental oxygen. We hypothesize that a novel strategy for oxygen delivery, solar-powered oxygen, can be implemented in remote locations and will be non-inferior to standard oxygen delivery by compressed gas cylinders.

Detailed Description

Arterial hypoxemia in pneumonia results from several mechanisms: pulmonary arterial blood flow to consolidated lung resulting in an intrapulmonary shunt, intrapulmonary oxygen consumption, and ventilation-perfusion mismatch. Hypoxemia is a risk factor for mortality in pediatric pneumonia, and was associated with a 5-fold increased risk of death in studies from Kenya and Gambia.

In one report from Nepal, the prevalence of hypoxemia (SpO2 \< 90%) in 150 children with pneumonia was 39% overall, with increasing rates of hypoxemia across strata of pneumonia severity (100% of very severe, 80% of severe and 17% of pneumonia patients). General features of respiratory distress were associated with hypoxemia in this study, including chest indrawing, lethargy, grunting, nasal flaring, cyanosis, inability to breastfeed or drink.

Few studies have reported on the use of solar powered oxygen (SPO2) delivery. One online report describes the use of a battery-powered oxygenator in the Gambia that could be adapted to use solar power (http://www.dulas.org.uk). Otherwise, our intervention is to our knowledge the first example of SPO2 delivery.

New ways to deliver oxygen for children with pneumonia in Africa could improve outcomes and save numerous lives. If this study documents the non-inferiority of SPO2 relative to standard oxygen delivery, this novel method of providing life-saving oxygen could be rolled out across centres in sub-Saharan Africa where oxygen cylinders are not widely available and electrical power is not reliable. The potential energy efficiency, low cost and ease of use make solar power an attractive avenue of investigation for use in resource-constrained settings. Proof-of-concept that the sun can be used to drive oxygen delivery could stimulate commercial interest in this technology. The SPO2 system could thus achieve rapid penetration into the most remote or rural settings in sub-Saharan Africa.

Study Timeline

• Study Start: 2014-02
• Study First Submitted: 2014-03-27
• Study First Submitted QC: 2014-03-31
• Study First Posted: 2014-04-01
• Primary Completion: 2015-06
• Study Completion: 2015-06
• Status Verified: 2016-09
• Last Update Submitted: 2016-09-14
• Last Update Posted: 2016-09-16

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 130

Inclusion Criteria

• Age <13 years
• IMCI defined pneumonia, severe pneumonia or very severe disease
• Hypoxemia (SpO2<90%) based on non-invasive pulse oximetry
• Hospital admission warranted based on clinician judgment
• Consent to blood sampling and data collection

Exclusion Criteria

• SpO2 ≥90%
• Suspected pulmonary tuberculosis
• Outpatient management
• Denial of consent to participate in study

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Solar powered oxygen	Solar powered oxygen	Solar panels used to drive an oxygen concentrator to deliver at stream of oxygen at approximately 90% FiO2 and a rate of 1-5L/min.
Oxygen from cylinders	Oxygen from cylinders	Conventional oxygen delivery from compressed gas cylinders

Primary Outcome Measures

Name	Time	Method
Length of hospital stay	Until end of hospitalization (usually 3 to 7 days)	The number of days from admission to discharge. Criteria for discharge are standardized and are assessed daily.

Secondary Outcome Measures

Name	Time	Method
Duration of supplemental oxygen therapy	Until hospital discharge (usually 3 to 7 days)	Time to wean patient off oxygen. This is assessed daily using standard procedures.
Cost	Until hospital discharge (usually 3 to 7 days)	Cost of oxygen cylinders (control arm) and cost of equipment (capital investment - solar oxygen intervention arm).
Lambaréné Organ Dysfunction Score (LODS)	Until hospital discharge (usually 3 to 7 days)	This simple published clinical score predicts mortality in children with malaria, but may also have prognostic value in pneumonia.
Mortality	At hospital discharge (usually 3 to 7 days)	In-hospital mortality will be quantified.
Proportion of patients successfully oxygenated	6 hours	Success defined as achieving a post-oxygen saturation above 90% within 6 hours.
Oxygen delivery system failure	During hospitalization (usually 3 to 7 days)	Failure defined as need for backup oxygen to maintain SpO2\>90%.

Trial Locations

Locations (1)

Jinja Regional Referral Hospital; 🇺🇬 Jinja, Uganda