Portable oxygen concentrator

Inogen G3 portable oxygen concentrator 2.2kg
A lightweight portable oxygen concentrator: Inogen One G3 (2,2 kg)
Sequal Equinox
Sequal Equinox, transportable concentrator with a high oxygen flow rate

A portable oxygen concentrator (POC) is a device used to provide oxygen therapy to people that require greater oxygen concentrations than the levels of ambient air. It is similar to a home oxygen concentrator (OC), but is smaller in size and more mobile. They are small enough to carry and many are now FAA-approved for use on airplanes.

Development

Medical oxygen concentrators were developed in the late 1970s. Early manufacturers included Union Carbide and Bendix Corporation[1]. They were initially conceived of as a method of providing a continuous source of home oxygen without the use of heavy tanks and frequent deliveries.[2] Beginning in the 2000s, manufacturers developed portable versions.[3] Since their initial development, reliability has been improved, and POCs now produce between one and six liters per minute (LPM) of oxygen depending the breathing rate of the patient.[4] The latest models of intermittent flow only products weighed in the range of from 2.8 to 9.9 pounds (1.3 to 4.5 kg) and continuous flow (CF) units were between 10 and 20 pounds (4.5 to 9.0 kg).[5][6]

How does it work?

POCs operate on the same principle as a home concentrator, pressure swing adsorption.[7] The basic set up of a POC is a miniaturized air compressor, a cylinder filled containing the sieve, a pressure equalizing reservoir and valves and tubes.

During the first half of the first cycle the internal compressor forces this air through a system of chemical filters known as a molecular sieve. This filter is made up of silicate granules called zeolite which attract (via adsorption) nitrogen molecules onto their surfaces more strongly than they attract oxygen molecules – this takes the nitrogen out of the air and concentrates the oxygen. When the desired purity is reached and the first cylinder reaches roughly 20 psi the oxygen and small amounts of other gases are released into the pressure equalizing reservoir. As the pressure in the first cylinder drops the nitrogen is desorbed, the valve is closed, and the gas is vented into the ambient air. Most of the oxygen produced is delivered to the patient; part is fed back into the sieves (at greatly reduced pressure) to flush away left over nitrogen, and prepare the zeolite for the next cycle.[8][9][10][11] The atmosphere contains around 21% oxygen and 78% nitrogen; the 1% remainder is a mixture of other gases and through this process. A POC system is functionally a nitrogen scrubber capable of consistently producing medical-grade oxygen of up to 90%.[11]

A Zen-O portable oxygen concentrator; it is capable of pulse and continuous flow operation

The most important consideration for a POC is its ability to supply adequate supplementary oxygen to relieve hypoxia (oxygen deficiency) during normal activities and based on the patients breathing cycles.[12][13] Other variables include maximum oxygen purity, the number and increment of settings for adjusting oxygen flow, and battery capacity (or number of add-on batteries) and power cord options for recharging.

Pulse dose

Pulse dose (also called intermittent-flow or on-demand) POCs are the smallest units, often weighing as little as 5 pounds (2.2 kg). Their small size enables the patient to not waste energy gained from the treatment on carrying them. Here the unit intermittently administers a volume (or bolus) of oxygen in milliliters per breath (mL/breath). Their ability to conserve oxygen is key to keeping the units so compact without sacrificing the duration of oxygen supply.[14] Most of the current POC systems provide oxygen on a pulse (on-demand) delivery and are used with a nasal cannula to deliver the oxygen to the patient.

Continuous flow

With continuous flow units, oxygen delivery is measured in LPM (liters per minute). Providing continuous flow requires a larger molecular sieve and pump/motor assembly, and additional electronics. This increases the device’s size and weight (approximately 18–20 lbs).[14]

There are some units available that are capable of functioning in either mode.

With on-demand or pulse flow, delivery is measured by the size (in milliliters) of the "bolus" of oxygen per breath.

Some uses

Medical:

Allows patients to utilize oxygen therapy 24/7 and reduce mortality as much 1.94 times less than for just overnight use.[15][16]
A Canadian study in 1999 concluded that an OC installation compliant to the proper regulations provides a safe, reliable, cost efficient primary hospital source of oxygen.[17]
Helps improve exercise tolerance, by allowing the user to exercise longer.[18]
Helps increase stamina throughout day-to-day activities.[19]
A POC is a safer option than carrying around an oxygen tank since it makes the purer gas on demand.[20]
POC units are consistently smaller and lighter than tank-based systems and can provide a longer supply of oxygen.[6][5]

Commercial:

Glass blowing industry[21]
Skin care[22]
Non-pressurized aircraft[23]
Nightclub oxygen bars[24] although doctors and the FDA have expressed some concern with this.[25]

FAA approval

On 13 May 2009, the United States Department of Transportation (DOT) ruled that air carriers conducting passenger flights of greater capacity than 19 seats, must allow travelers with a disability to use an FAA-approved POC. The DOT rules have been adopted by many international airlines. A list of POCs approved for air travel is on the FAA website.[26]

Nighttime use

On-demand units are not advised for patients that experience oxygen desaturation due to sleep apnea, and a CPAP mask is generally advised for them.[14] For patients whose desaturation is due to shallow breathing, the nighttime use of POCs is a useful therapy.[15] Especially with the advent of alarms and technology that detects a patient's slower breathing during sleep and adjusts the flow or bolus size accordingly.[27]

See also

References

  1. "The History of Oxygen Concentrators & Their Future!". DME Library. Retrieved 26 April 2018.
  2. "A Short History of Long Term Oxygen Therapy". Inspired Respiratory Care. Retrieved 26 April 2018.
  3. "History of Oxygen Concentrators". Inogen.com. Retrieved 26 April 2018.
  4. "Key Issues in Oxygen Therapy with Conserving Devices: Part II". Inspired Respiratory Care. Retrieved 26 April 2018.
  5. 1 2 A Guide to Portable Oxygen Concentrators, American Association for Respiratory Care (AARC), 2013, retrieved 12 April 2016
  6. 1 2 "Portable Oxygen Concentrators Comparison Charts". Vitality Medical. Retrieved 26 April 2018.
  7. Sircar, Shivaji (2002). "Pressure Swing Adsorption". Ind. Eng. Chem. Res. 41 (6): 1389–92. doi:10.1021/ie0109758. Retrieved 26 April 2018.
  8. United States Grant US4477264A, "Pressure swing adsorption process for a medical oxygen generator for home use", published 16 October 1984
  9. United States Grant US5827358A, "Rapid cycle pressure swing adsorption oxygen concentration method and apparatus", published 27 October 1998
  10. "How do Portable Oxygen Concentrators work?". Oxygensolutions.com. Retrieved 26 April 2018.
  11. 1 2 "How Does My Oxygen Concentrator Work?". oxygenworldwide.com. Retrieved 26 April 2018.
  12. "Oxygen Delivery Fundamentals". Inspired Respiratory Care. Retrieved 26 April 2018.
  13. Jindal, S.K. (2008). "Oxygen Therapy: Important Considerations" (PDF). Indian J Chest Dis Allied Sci. 50: 97–107. Retrieved 26 April 2018.
  14. 1 2 3 "Continuous Flow vs. Pulse Dose". business.com. Home Medical Equipment Business. Retrieved 27 January 2015.
  15. 1 2 Stoller, J.K.; Panos, R.J.; Krachman, S.; Doherty, D.E.; Make, B. (July 2010). "Oxygen therapy for patients with COPD: current evidence and the long-term oxygen treatment trial". Chest. 138 (1): 179–87. PMID 20605816.
  16. "Continuous or nocturnal oxygen therapy in hypoxemic chronic obstructive lung disease: a clinical trial. Nocturnal Oxygen Therapy Trial Group". Annals of Internal Medicine. 93 (3): 391–98. September 1980. PMID 6776858.
  17. Friesen, R.M.; Raber, M.B.; Reimer, D.H. (December 1999). "Oxygen concentrators: a primary oxygen supply source". Canadian Journal of Anaesthesia. 46 (12): 1185–90. doi:10.1007/BF03015531. PMID 10608216.
  18. Emtner, M.; Porszasz, J.; Burns, M.; Somfay, A.; Casaburi, R. (1 November 2003). "Benefits of supplemental oxygen in exercise training in nonhypoxemic chronic obstructive pulmonary disease patients". American Journal of Respiratory and Critical Care Medicine. 168 (9): 1034–42. PMID 12869359.
  19. "Supplemental Oxygen". The Wayback Machine. American Lung Association. Retrieved 26 April 2018.
  20. "Top Ten Safety Musts for Portable Oxygen Therapy". 1st Class Medical. Retrieved 26 April 2018.
  21. "Oxygen Concentrators Make your own Oxygen for Torches". Sundance Art Glass. Retrieved 26 April 2018.
  22. Wenborg M.D., Craig. "The Esthetic Benefits of Oxygen Skin Care". Skin Inc. Magazine. Retrieved 26 April 2018.
  23. "Continuous oxygen supply for non-pressurised cabins". The Wayback Machine. Oxyfly. Retrieved 26 April 2018.
  24. Meek, James. "It's a gas". theguardian.com. The Guardian. Retrieved 26 April 2018.
  25. Thomas, Jennifer. "Oxygen Bars Not a Breath of Fresh Air". Health Day. Retrieved 26 April 2018.
  26. FAA Approves Portable Oxygen Concentrators
  27. Waters, Allison (7 November 2012). "Choosing the Best Portable Oxygen Concentrator: Start with the Flow". POC News & More. Retrieved 30 July 2014.
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