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Vaccine Storage

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Vaccine in cold storage

Vaccine storage relates to the proper vaccine storage and handling practices from their manufacture to the administration in people.[1] The general standard is the 2–8 °C cold chain for vaccine storage and transportation. This is used for all current US Food and Drug Administration (FDA)-licensed human vaccines and in low and middle-income countries. Exceptions include some vaccines for smallpox, chickenpox, shingles and one of the measles, mumps, and rubella II vaccines, which are transported between −25 °C and −15 °C.[2][3] Some vaccines, such as the COVID-19 vaccine, require a cooler temperature between −80 °C and −60 °C for storage.[3]

In 1996, the World Health Organization (WHO) decided to spread vaccines worldwide. This urges researchers to design storage for vaccines without losing its potency. Since then, the production of vaccines has spiked, and various kinds of vaccines have their handling practices. WHO has set standards to ensure cold chain and has different types of storage, including refrigerators, freezers, cold boxes, and vaccine carriers. Different types of thermometers are also used because a slight temperature change could result in loss of potency.

History

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Vaccine Storage was first developed in the early 1960s, where the infectious smallpox disease outbreaks. During this time, vaccine technology was available and offered for protection. Since smallpox has been one of the deadliest diseases known, the World Health Organization (WHO) prepared to launch a campaign to spread the vaccines and end smallpox in 1966.[4] It was not until 1974 where WHO first introduced the Expanded Programme on Immunization (EPI). [5] The main goal was to make immunization available to every child worldwide by 1990. Immunization of six illnesses was being transported, including tuberculosis, diphtheria, pertussis, tetanus, measles, and polio.[4][6] Dr. Rafe Henderson, the first director of EPI, designed a plan to deliver temperature-sensitive vaccines across dozens of countries safely.[7] It was an important step to ensure that the vaccines were maintained in their determined conditions and guides towards the development of the cold chain.[8] The WHO supported countries worldwide to ensure the vaccine cold chain is maintained.[2][4]

The cold chain has been implemented for years. After EPI was initiated, over 700,000 measles deaths were prevented, and millions of the target diseases have been prevented.[6] There has been a huge milestone in the vaccine industry as scientists create more vaccines for new types of diseases. Therefore, it has a direct impact on the cost of transportation and different kinds of refrigerator storage either at +2° to +8°C or +20° to +25°C.[4] This urge EPI to create a strategy to encompasses both vaccines and medicines to be able to sustain their components without the need of storage. The term 'cold chain' has now been replaced with 'supply chain'.[4] The current system of vaccine cold chain still continues for delivering particular vaccines. WHO has made improvements by introducing the "controlled temperature chain" (CTC), which is an innovative approach allowing the vaccine to be taken out of the cold chain for a limited period of time, but CTC is still in the development process and will not be available for all vaccines for many years.[9] Nowadays, engineers is still thinking of a way to eliminate refrigeration at +2 to +8C from the entire supply chain for all vaccines. With the initiatives of reducing temperature sensitivity of vaccines and regulation permits, it could eliminate the need for refrigeration in the supply chain. It will be suitable for an undeveloped country as less handling of vaccines needs to be done.[4][9][8][6]

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The cold chain has been one of the most reliable supply chains for transporting vaccines around the globe. Since vaccines are sensitive biological products, proper storage and handling of vaccines are important to ensure the potency of vaccines is not lost.[1][2][8] Vaccines must be continuously monitored as each has different reactivity to low temperature, high temperature, and light.[10]

The majority of vaccines required storage temperature of +35° to +46°F (+2° to +8°C) and must not be exposed to freezing temperature.[11] Temperature to cold can result in an irreversible reaction that reduces vaccines potency and loss in adjuvant effect. Certain vaccines contain adjuvants (aluminum) that will precipitate when exposed to freezing temperatures.[12] Temperature too hot could also result in wanted viruses permanently degrading and losing potency. However, the effects are usually smaller, gradual, and predictable than from freezing temperatures. [13] Visible signs of physical changes after exposure to undesirable temperature are not necessary to result in a decrease of vaccine potency.[14]

Vaccine Storage and Handling Requirements

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Health facilities use storage called purpose-built units (also referred to pharmaceutical-grade units). These refrigerators or freezers are specifically designed for the storage of biologics, including vaccines. These units differ from standard household-grade units since it has microprocessor-based temperature control with a digital temperature sensor (thermistor, thermocouple, or resistance temperature detector), and fan-forced air circulation to promote uniform temperature around the unit.[12] These storage are usually a stand-alone refrigerator or freezers because they perform better at keeping the temperature constant.

A Household-grade refrigerator can also be an acceptable alternative to purpose-built units. However, the freezer compartment of this type is not recommended to store vaccines, and vaccines should be stored centrally inside the refrigerator. Many combination units cool the refrigerator using air from the freezer, resulting in different temperature zones inside the fridge.[11] Placing vaccines near the cold air output from the freezer could cause too low temperature, and placing it at the very bottom of the refrigerator could cause too high temperature. It is important not to place vaccines near the storage unit doors because it affects the temperature and exposes vaccines to light, reducing potency for some vaccines.[13]

Types of Vaccine Storage

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WHO has set standards to ensure the cold chain types of equipment can sustain different vaccines in health facilities.

Refrigerators

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Stand alone refrigerator is being used to store vaccines

Refrigerators are the most common type of storage in health facilities as they can hold many vaccines in one single unit. This storage will help temperature-sensitive vaccines to withstand their components, and the surrounding area will always remain between +2° to +8°C. In developed countries, electric refrigerators (compression units) are wildly used as there is an electricity supply for at least 8 hours per day. If the country doesn't have sufficient electricity, the solar energy refrigerator (photovoltaic units) or bottled gas/kerosene (absorption units) is also reliable. It is important to keep the desired temperature in any of the models in any circumstances and should not be changed.[1][15][10]

Freezers

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Freezers act the same way as refrigerators but for extreme temperatures. Its minimum temperature depends on the manufacture. Typically this storage is to store frozen vaccines and maintained temperature between -80 to -15C. Health facilities use purpose-built or pharmaceutical-grade units and vary in size.[16]

Cold boxes

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Cold chain being maintained using ice box while transporting covid-19 vaccine

Cold boxes are typically used to carry around vaccines around the area. It is a self-supporting container with insulation and ice-packs surrounding the interior to keep vaccines at low temperatures.[17] Unlike the refrigerator, the cold box has limited time to maintain temperatures below +10°C, normally 48-96 hours.[18] It comes in many different types and shapes, and this storage is very useful for the transportation of vaccines in or out of the health facility.[10]

Vaccine carriers

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Vaccine carriers are similar to cold boxes, but they are smaller and easier to carry around. This small carrier is also packed with ice packs to keep the vaccine at a low temperature.[10] However, they do not stay cold for as long as cold boxes, at most 36-48 hours.[17] It is generally used for transporting from a health facility to outreach sites.[18]

Water packs

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Water packs are flat and leak-proof plastic containers used in the interiors of cold boxes and vaccine carriers.[19] These containers are set to the appropriate temperature depending on the type of vaccine being transported. The temperature could range from -10° to +24°C and does not last that long before coming back to the same temperature as the surroundings.[10]

Foam pads

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Foam pads are used to cover the lid of cold boxes and vaccine carriers, protecting the vaccine vials from damage during transportation and external heat. It is just a soft sponge that ensures the vials stay in place and prolong the desired temperature inside the containers.[10][20]

Temperature Monitoring

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Temperature plays a crucial part in maintaining the potency of vaccines.[14] Although the risk of storage cooler malfunction is low, it is better to check than the need to replace vaccines wasted due to the loss of potency. Temperature monitoring needs to take place in both storage units and transport units. The refrigerator should maintain a temperature between 2° to 8°C (36° to 46°F). Freezers should maintain a temperature between -50° to -15°C (-58° to +5°F).[12] Thermometers are useful to monitor the temperature by placing at the storage unit's central location, adjacent to the vaccines.

Every vaccine storage unit must have a temperature monitoring device. There are many different thermometers, including standard fluid-filled, min-max, and continuous temperature monitoring devices. Each type of thermometer has its advantages and disadvantage.[13]

Table 1. Comparison of thermometers used to monitor vaccine temperature
Thermometer Type Advantages Disadvantages
Standard fluid-filled[12]
  • Inexpensive and simple to use
  • Thermometers encased in biosafe liquids can reflect vaccine temperature more accurately
  • Less accurate (+/-1°C)
  • No information on duration of out specification exposure
  • No information on min/max temperatures
  • Cannot be recalibrated
  • Inexpensive models might performed poorly
Min-max[12]
  • Inexpensive
  • Monitors temperature range
  • Less accurate (+/-1°C)
  • No information on duration of out specification exposure
  • Cannot be recalibrated
Continuous temperature

monitoring device[12]

  • Most accurate
  • Continuous 24-hour readings of temperature range and duration
  • Can be recalibrated at regular intervals
  • alert capability to notify of temperature excursions
  • Most expensive
  • Requires most training and maintenance

Health facilities use the digital data logger (DDL) as their temperature monitoring device. This continuous temperature monitoring device uses a buffered temperature probe, the most accurate way to measure actual vaccine temperature.[21][22] The DDL also includes details on how long a unit has been operating outside the temperature range and record all temperatures at present intervals. Temperature probes are also designed to prevent false readings by protecting the thermometer from sudden temperature changes when opening a refrigerator door.[23]

Applications

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The breakthrough of vaccines has changed the health industry, and numerous vaccines are still being developed nowadays. Each type of vaccine has its standard to keep wanted components intact.

Table 2. Vaccine storage temperature recommendations
Vaccines Vaccine type Formulation Adjuvent Recommended temperature Description
Cholera[24] Inactivated bacteria Liquid +/- buffer granules None 2° - 8°C Freeze sensitive
Covid-19[25][3] mRNA Liquid None -90° - -60°C Not freeze sensitive but unstable when exposure to heat
Hepatitis A (HAV)[26] Inactivated virus Liquid Usually AlOH3 2° - 8°C relatively heat stable (resistance to 25° - 37°C for several months), but are freeze sensitive
Hepatitis B (HepB)[27][28] Recombinant protein Liquid AlOH3 2° - 8°C one of the most heat-stable vaccines (resistance for months at 20° -25°C and weeks at 37C), but also freeze sensitive.
Human papillomavirus (HPV)[29] Recombinant protein (VLP) Liquid Al hydroxylphosphate sulfate 2° - 8°C Very stable. They are heat resistant and do not affect overall shelf life, but are freeze and light sensitive.
Influenza[30] Inactivated (split/whole) Liquid None 2° - 8°C Can be stable for several weeks at room temperature. But are freeze sensitive
Live attenuated virus Liquid or lyophilized None 2° - 8°C Can be damaged by freezing and have short shelf life.
Measles[31] Live attenuated virus Lyophilized None -50° - 8°C Moderately stable. Potency is retained at high temperature and also can be stored frozen at -20°C.
Meningococcal[32] PS Lyophilized None 2° - 8°C Not freeze sensitive as most of the vaccines need to be stored frozen. Have good stability at room temperature.
PS-PVC Liquid or Lyophilized AlOH3/None 2° - 8°C Some of the vaccines are not freeze sensitive and appear to be relatively stable.
Polio[33] Live attenuated virus Liquid None -20° - 8°C Can be frozen and stable at -20°C. Relatively heat sensitive.
Inactivated virus (whole) Liquid None 2° - 8°C Freeze sensitive but relatively heat stable.
Rabies[34] Inactivated virus (whole) Usually lyophilized Usually none 2° - 8°C very stable in lyophilized form and not freeze sensitive
Rubella[35] Live attenuated virus Lyophilized None -50° - 8°C Can be stored at -20°C and more stable than measles vaccines
Tetanus toxoid[36] Purified protein Liquid Aluminum based 2° - 8°C Very heat stable and resistant to temperature up to 55°C, but freeze sensitive.
Tuberculosis[37] Live attenuated baacterium Lyophilized None 2° - 8°C Not freeze and light sensitive
Varicella[38][39] Live attenuated virus Lyophilized None -50°C - -15°C Not freeze sensitive. but relatively unstable at elevated. temperature

Due to the abundant number of vaccines, pharmaceutics combines two or more vaccines to save more time. These types of vaccines might change in storage temperature recommendation due to the additional stability of each vaccine.

Table 3. Combination vaccines storage temperature recommendation
Vaccine General name Vaccine type Formulation Adjuvant Recommended temperature Description
Diphtheria, tetanus, pertussis[40] DTaP Purified protein Liquid Al based 2° - 8°C Freeze sensitive
DTwP Purified protein, Inactivated bacteria Liquid Al based 2° - 8°C Freeze sensitive but relatively heat stable
Hepatitis A and B[41] Recombinant protein, inactivated virus Liquid Al based 2° - 8°C Freeze sensitive but relatively heat stable
Measles, mumps, and rubella[42] MMR Live attenuated virus Lyophilized None -50° - 8°C Not freeze sensitive and relatively stable in the lyophilized state.

See also

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References

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  1. ^ a b c "Vaccine Storage and Handling Resources | CDC". www.cdc.gov. 29 March 2021. Archived from the original on 2 April 2021. Retrieved 2 April 2021. {{cite web}}: |archive-date= / |archive-url= timestamp mismatch; 19 March 2021 suggested (help)
  2. ^ a b c "The cold chain". Immunization in Practice: A Practical Guide for Health Staff. World Health Organization. 2015. ISBN 978-92-4-154909-7.
  3. ^ a b c James, Eric R (11 March 2021). "Disrupting vaccine logistics". International Health. 13 (3): 211–214. doi:10.1093/inthealth/ihab010. PMC 8079314. PMID 33709112. Archived from the original on 2 April 2021. Retrieved 2 April 2021.
  4. ^ a b c d e f Lloyd, John; Cheyne, James (2017-04-19). "The origins of the vaccine cold chain and a glimpse of the future". Vaccine. Building Next Generation Immunization Supply Chains. 35 (17): 2115–2120. doi:10.1016/j.vaccine.2016.11.097. ISSN 0264-410X.
  5. ^ "Essential Programme on Immunization". www.who.int. Retrieved 2021-11-10.
  6. ^ a b c Keja, K.; Chan, C.; Hayden, G.; Henderson, R. H. (1988). "Expanded programme on immunization". World Health Statistics Quarterly. Rapport Trimestriel De Statistiques Sanitaires Mondiales. 41 (2): 59–63. ISSN 0379-8070. PMID 3176515.
  7. ^ "Dr. Ralph "Rafe" Henderson". www.cdc.gov. 2019-01-17. Retrieved 2021-11-10.
  8. ^ a b c "About the Cold Chain". Global Cold Chain Alliance. 2018-02-14. Retrieved 2021-11-10.
  9. ^ a b "Current projects - norms and Standards for Pharmaceuticals". www.who.int. Retrieved 2021-11-10.
  10. ^ a b c d e f World Health Organization (2015). Immunization in practice: a practical guide for health staff. World Health Organization.
  11. ^ a b Gazmararian, Julie A.; Oster, Natalia V.; Green, Diane C.; Schuessler, Linda; Howell, Kelly; Davis, Janona; Krovisky, Marybeth; Warburton, Samuel W. (2002-11). "Vaccine storage practices in primary care physician offices: assessment and intervention". American Journal of Preventive Medicine. 23 (4): 246–253. doi:10.1016/s0749-3797(02)00512-3. ISSN 0749-3797. PMID 12406478. {{cite journal}}: Check date values in: |date= (help)
  12. ^ a b c d e f "ACIP Storage and Handling Guidelines for Immunization | CDC". www.cdc.gov. 2021-04-21. Retrieved 2021-11-18.
  13. ^ a b c "Notice to Readers: Guidelines for Maintaining and Managing the Vaccine Cold Chain". www.cdc.gov. Retrieved 2021-11-18.
  14. ^ a b Nayda, Claire; Miller, Nan C.; Kempe, Ann (2001). Immunisation keep it cool: the vaccine cold chain: guidelines for immunisation providers on maintaining the cold chain. Australia, Immunise Australia Program (2nd ed ed.). Canberra: Commonwealth Department of Health and Aged Care. ISBN 978-0-642-73524-9. {{cite book}}: |edition= has extra text (help)
  15. ^ "What You Need to Know to Store Vaccines in Refrigerators". Default. Retrieved 2021-11-10.
  16. ^ "Vaccine Storage Solutions - US". www.thermofisher.com. Retrieved 2021-11-19.
  17. ^ a b "OLCreate: HEAT_IM_ET_1.0 Immunization Module: The Cold Chain: 6.2.2  Cold boxes and vaccine carriers". www.open.edu. Retrieved 2021-11-10. {{cite web}}: no-break space character in |title= at position 68 (help)
  18. ^ a b "Cold chain technical support". www.unicef.org. Retrieved 2021-11-10.
  19. ^ "OLCreate: HEAT_IM_ET_1.0 Immunization Module: The Cold Chain: 6.2.3  Ice-packs". www.open.edu. Retrieved 2021-11-10. {{cite web}}: no-break space character in |title= at position 68 (help)
  20. ^ "OLCreate: HEAT_IM_ET_1.0 Immunization Module: The Cold Chain: 6.2.4  Foam pads". www.open.edu. Retrieved 2021-11-10. {{cite web}}: no-break space character in |title= at position 68 (help)
  21. ^ "Digital Data Loggers – California Vaccines for Children (VFC)". eziz.org. Retrieved 2021-11-18.
  22. ^ SmartSense. "Digital Data Loggers (DDL): Recommended by CDC for Vaccine Storage & Handling". blog.smartsense.co. Retrieved 2021-11-18.
  23. ^ Schroeder, Miranda. "Temperature Probes: The Benefits of a Solid Thermal Ballast". blog.helmerinc.com. Retrieved 2021-11-18.
  24. ^ "Cholera Vaccine (Cholera Vaccine): Uses, Dosage, Side Effects, Interactions, Warning". RxList. Retrieved 2021-11-19.
  25. ^ "Administration Overview for Pfizer-BioNTech COVID-19 Vaccine | CDC". www.cdc.gov. 2021-11-17. Retrieved 2021-11-19.
  26. ^ "VAQTA Paediatric - Summary of Product Characteristics (SmPC) - (emc)". www.medicines.org.uk. Retrieved 2021-11-19.
  27. ^ "Engerix B 20 micrograms/1 ml Suspension for injection in pre-filled syringe - Summary of Product Characteristics (SmPC) - (emc)". www.medicines.org.uk. Retrieved 2021-11-19.
  28. ^ "Fendrix - Summary of Product Characteristics (SmPC) - (emc)". www.medicines.org.uk. Retrieved 2021-11-19.
  29. ^ "HPV Vaccine Storage and Handling | CDC". www.cdc.gov. 2021-04-06. Retrieved 2021-11-19.
  30. ^ "Flu Vaccine Storage - SD Dept. of Health". doh.sd.gov. Retrieved 2021-11-19.
  31. ^ "Storage and Handling for M-M-R®II (Measles, Mumps, and Rubella Virus Vaccine Live)". MerckVaccines.com. Retrieved 2021-11-19.
  32. ^ "Meningococcal Vaccines Storage and Handling | CDC". www.cdc.gov. 2021-10-21. Retrieved 2021-11-19.
  33. ^ Sokhey, J.; Gupta, C. K.; Sharma, B.; Singh, H. (1988-02). "Stability of oral polio vaccine at different temperatures". Vaccine. 6 (1): 12–13. doi:10.1016/0264-410x(88)90006-0. ISSN 0264-410X. PMID 3354252. {{cite journal}}: Check date values in: |date= (help)
  34. ^ "Rabies vaccine found effective even after warm storage". WSU Insider. Retrieved 2021-11-19.
  35. ^ "Storage and Handling for M-M-R®II (Measles, Mumps, and Rubella Virus Vaccine Live)". MerckVaccines.com. Retrieved 2021-11-19.
  36. ^ "Storage and Handling for Diphtheria, Tetanus, and Pertussis Vaccines | CDC". www.cdc.gov. 2020-01-23. Retrieved 2021-11-19.
  37. ^ "Minnesota Department of Health". www.health.state.mn.us. Retrieved 2021-11-19.
  38. ^ "SOM - State of Michigan". www.michigan.gov. Retrieved 2021-11-19.
  39. ^ "Storage and Handling for VARIVAX® (Varicella Virus Vaccine Live)". MerckVaccines.com. Retrieved 2021-11-19.
  40. ^ "Vaccine Accidentally Left Out of the Refrigerator? 5 Steps to Take". Default. Retrieved 2021-11-19.
  41. ^ "Storage for RECOMBIVAX HB® [Hepatitis B Vaccine (Recombinant)]". MerckVaccines.com. Retrieved 2021-11-19.
  42. ^ "Storage and Handling for M-M-R®II (Measles, Mumps, and Rubella Virus Vaccine Live)". MerckVaccines.com. Retrieved 2021-11-19.