Oxygen and Ventilator Logistics During California's COVID-19 Surge: When Oxygen Becomes a Scarce Resource

A practical approach to preparing your ICU for epidemics and pandemics

PURPOSE OF REVIEW

Major outbreaks of infectious diseases, including epidemics and pandemics, are increasing in scope and frequency, threatening public health and straining the capacity of health systems worldwide. High-consequence infectious diseases (HCIDs), including highly pathogenic respiratory viruses and viral hemorrhagic fevers, are both contagious and virulent, and these pathogens thus are topics of special concern for pandemic planning.

RECENT FINDINGS

The COVID-19 pandemic demonstrated how a major disease outbreak can negatively impact all aspects of hospital functioning. Identification of patients with HCIDs needs careful clinical evaluation and coordination with public health authorities. Staff safety and patient care require appropriate infection prevention precautions, including personal protective equipment. Surges of ill patients may lead to significant strain, with increased ICU patient mortality. Strategies to reduce the impact of surge appear to reduce mortality, such as tiered staffing models and load-leveling across health systems.

SUMMARY

Pandemics and HCIDs are a significant threat to global health, and ICUs play a major role in the care of affected patients. Critical care professionals must work to ensure that our hospitals are prepared to identify and care for these patients in advance of the next emergency.

Hospital Oxygen Supply Overwhelmed Due to COVID-19: When Demand Exceeds Supply

BACKGROUND

During the first wave of COVID-19, we experienced problems with our hospital oxygen supply system. This study aimed to analyze factors that stressed this system and rethink the design criteria of the gas pipeline system considering the varying oxygen demand.

METHODS

A retrospective study was conducted to describe problems that occurred at different stages in the oxygen supply system at our hospital due to increases in oxygen use in general, and the creation of an intermediate respiratory care unit (IRCU) and use of high-flow nasal cannula (HFNC) in particular. Herein, the characteristics and design criteria of the medical gas pipeline system are analyzed, and the steps taken to avoid future problems are outlined.

RESULTS

Increases in oxygen use were observed at times of maximum occupancy, and these created vulnerabilities in the oxygen supply due to insufficient capacity in terms of cryogenic tanks, evaporators, and the piping network. The peak consumption was 3 times higher than the peak in the preceding 4 years. The use of HFNC therapy aggravated the problem; IRCU use accounting for as much as two-fifths of the total across the hospital. Steps taken subsequently prevented the recurrence of vulnerabilities.

CONCLUSIONS

The design criteria for storage and distribution networks of medical gases in hospitals need to be revised considering new parameters for their implementation and the use of HFNC therapy in an IRCU. In particular, the cryogenic tanks, evaporators, and piping network for hospital wards are critical.

Novel design of inspiratory flow generation and gas mixing for critical care ventilators suitable for rapid production and mass casualty incidents

Scarcity of medical resources inspired many teams worldwide to design ventilators utilizing different approaches during the recent COVID-19 pandemic. Although it can be relatively easy to design a simple ventilator in a laboratory, a large scale production of reliable emergency ventilators which meet international standards for critical care ventilators is challenging and time consuming. The aim of this study is to propose a novel and easily manufacturable principle of gas mixing and inspiratory flow generation for mechanical lung ventilators. Two fast ON/OFF valves, one for air and one for oxygen, are used to control the inspiratory flow generation using pulse width modulation. Short gas flow pulses are smoothed by low-pass acoustic filters and do not propagate further into the patient circuit. At the same time, the appropriate pulse width modulation of both ON/OFF valves controls the oxygen fraction in the generated gas mixture. Tests focused on the accuracy of the delivered oxygen fractions and tidal volumes have proved compliance with the international standards for critical care ventilators. The concept of a simple construction using two fast ON/OFF valves may be used for designing mechanical lung ventilators and thus suitable for their rapid production during pandemics.

Technical Innovation in Critical Care in a World of Constraints: Lessons from the COVID-19 Pandemic

The COVID-19 crisis was characterized by a massive need for respiratory support, which has unfortunately not been met globally. This situation mimicked those which gave rise to critical care in the past. Since the polio epidemic in the 50's, the technological evolution of respiratory support has enabled health professionals to save the lives of critically-ill patients worldwide every year. However, much of the current innovation work has turned around developing sophisticated, complex, and high-cost standards and approaches whose resilience is still questionable upon facing constrained environments or contexts, as seen in resuscitation work outside intensive care units, during pandemics, or in low-income countries. Ventilatory support is an essential life-saving tool for patients with respiratory distress. It requires an oxygen source combined to a ventilatory assistance device, an adequate monitoring system, and properly trained caregivers to operate it. Each of these elements can be subject to critical constraints, which we can no longer ignore. The innovation process should incorporate them as a prima materia, whilst focusing on the core need of the field using the concept of frugal innovation. Having a universal access to oxygen and respiratory support, irrespective of the context and constraints, necessitates: i) developing cost-effective, energy-efficient, and maintenance-free oxygen generation devices; ii) improving the design of non-invasive respiratory devices (for example, with oxygen saving properties); iii) conceiving fully frugal ventilators and universal monitoring systems; iv) broadening ventilation expertise by developing end-user training programs in ventilator assistance. The frugal innovation approach may give rise to a more resilient and inclusive critical care system. This paradigm shift is essential for the current and future challenges.

India's Multi-Sectoral Response to Oxygen Surge Demand during COVID-19 Pandemic: A Scoping Review

Oxygen support became one of the rate-limiting steps for medical care during COVID-19 pandemic in India. The primary aim of this study was to appraise the manufacturing, supply, and distribution of medical oxygen during the pandemic. The secondary objectives were to highlight the coordination of various stakeholders to mitigate the oxygen surge and to present a critical analysis of India's response to the emergent situation. Using an analytic approach, we have delineated India's response to mitigate the medical oxygen surge during the distressing second peak between March-May 2021. In the pre-COVID-19 era, of the total 6900 MT of oxygen produced in India, only 1000 MT was available for medical usage, which was increased up to 19940 MT through the strengthening of in-house oxygen manufacturing, low-cost innovations, and enhanced storage facilities. High-burden states were identified, and transport was facilitated through departments of railways, defence and civil aviation. Real-time scrutiny of the oxygen supply was provided. Essential customs duties on importing oxygen and vital equipment were exempted, along with other swift decisions. National Oxygen Stewardship Program' was initiated to build the capacity of health care workers in oxygen therapy and rational use of surplus oxygen. The pandemic overwhelmed the health system. But a coordinated multi-stakeholder approach facilitated the fight against oxygen surge. However, a comprehensive pandemic response will need more than just oxygen. This resourceful utilization offers a silver lining and facilitates the improvement of health systems and health outcomes in the long term.

Porterville Alternate Care Site Provision of Oxygen at COVID-19 Pandemic Peak

During the COVID-19 pandemic peak, the author deployed twice to an emergency Alternate Care Site in Porterville, California. The provision of oxygen to patients there, as seen from a physician's perspective, does not fully support the description in a recently published article of how the State of California approached oxygen logistics during the COVID-19 surge. To inform future planning, an adequate logistical assessment must include not only approaches for solving technical resource challenges, but also reliable numbers regarding end-user resource utilization, and non-utilization, as well as program costs, benefits, and unintended consequences.

Shortages and Vulnerabilities of Hospital Oxygen Systems

The COVID-19 pandemic has inundated hospitals with patients suffering from profound hypoxemia and placed a strain on health care systems around the world. Shortages of personnel, drugs, ventilators, and beds were predicted and, in many cases, came to fruition. As the pandemic wore on, there have been reports of impacts on hospital medical gas supply systems. Oxygen in particular has been a concern for hospitals in terms of supply and distribution. This article outlines procedures for estimating medical gas flow limitations within health care organizations and also methods for estimating gas consumption.

Reduction in Hospital Transfers at a US COVID-19 Alternate Care Site: Maintaining Surge Capacity Support in Imperial County, California

OBJECTIVE

The transfer rate for patients from an Alternate Care Site (ACS) back to a hospital may serve as a metric of appropriate patient selection and the ability of an ACS to treat moderate to severely ill patients accepted from overwhelmed health-care systems. During the coronavirus infectious disease 2019 (COVID-19) pandemic, hospitals worldwide experienced acute surges of patients presenting with acute respiratory failure.

METHODS

An ACS in Imperial County, California was re-established in November 2020 to help decompress 2 local hospitals experiencing surges of COVID-19 cases. The patients treated often had multiple comorbid illnesses and required a median supplemental oxygen of 3 L/min (LPM) on admission. Numerous interventions were initiated during a 2-wk period to improve clinical care delivery.

RESULTS

The objectives of this retrospective observational study are to evaluate the impact of these clinical and staff interventions at an ACS on the transfer rate and to provide issues to consider for future ACS sites managing COVID-19 patients.

CONCLUSIONS

The data suggest that continuous, real-time process-improvement interventions helped reduce the transfer rate back to hospitals from 36.7% to 14.5% and that an ACS is a viable option for managing symptomatic COVID-19 positive patients requiring hospital-level care when hospitals are overburdened.

Limited Utility of Self-made Oxygen Generators Assembled From Everyday Commodities During the COVID-19 Pandemic

The current COVID-19 pandemic has aggravated pre-existing oxygen supply gaps all over the world. In fact, oxygen shortages occurred in affluent areas with highly developed healthcare systems. The state-of-affairs created much suffering and resulted in potentially preventable deaths. Meanwhile, several international activities have been initiated to improve oxygen availability in the long-term by creating new networks of oxygen plants and supply channels. However, disasters such as the current pandemic may require rapid, autarkic oxygen production. Therefore, we determined whether oxygen resilience could conceivably be improved through self-made oxygen generators using material that is easily available even in remote areas. The team comprised engineers and physicians with hands-on experience in low- and middle-income countries. We constructed and tested self-made setups for water hydrolysis and membrane-based oxygen purification. We must conclude, however, that the massive amounts of oxygen patients with COVID-19 require cannot be reasonably met with such simple measures, which would require high efforts and hold potential risks.

Utilization of Alternate Care Sites During the COVID-19 Surge and Mass Care: California, 2020-2021

The coronavirus disease (COVID-19) pandemic caused critical hospital bed and staffing shortages in parts of California for most of 2020 and 2021. Alternate Care Sites (ACS) were established in several regions to alleviate the hospital patient surge and to maximize staffed bed capacity. Over 1900 patients were successfully provided medical care (with physician, nursing, respiratory therapy, oxygen, and pharmacy services) in relatively austere settings. This paper examines the challenges faced at these ACS facilities and how adaptations were incorporated according to the changing dynamics of the COVID-19 pandemic to successfully manage higher acuity patients. ACS facilities were 1 approach to California's surge of COVID-19 patients, despite limited medical supplies and staffing.