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Pandemic Incident Management for Vaccine Safety Challenges: Victoria’s Alert Advisory Group Experience

Published online by Cambridge University Press:  03 September 2024

Hazel J. Clothier*
Affiliation:
Epi-Informatics, Centre for Health Analytics, Melbourne Children’s Campus, Victoria, Australia Surveillance of Adverse Events Following Vaccination in the Community (SAEFVIC), Murdoch Children’s Research Institute, Melbourne, Victoria, Australia COVID-19 Response, Department of Health Victoria, Melbourne, Australia Department of Pediatrics, The University of Melbourne, Melbourne, Victoria, Australia
Michelle Wolthuizen
Affiliation:
COVID-19 Response, Department of Health Victoria, Melbourne, Australia
Ingrid Laemmle-Ruff
Affiliation:
Surveillance of Adverse Events Following Vaccination in the Community (SAEFVIC), Murdoch Children’s Research Institute, Melbourne, Victoria, Australia
Georgina Lewis
Affiliation:
Surveillance of Adverse Events Following Vaccination in the Community (SAEFVIC), Murdoch Children’s Research Institute, Melbourne, Victoria, Australia
Catherine Radkowski
Affiliation:
Immunisation Unit, Department of Health Victoria, Melbourne, Australia
Jim Buttery
Affiliation:
Epi-Informatics, Centre for Health Analytics, Melbourne Children’s Campus, Victoria, Australia Surveillance of Adverse Events Following Vaccination in the Community (SAEFVIC), Murdoch Children’s Research Institute, Melbourne, Victoria, Australia COVID-19 Response, Department of Health Victoria, Melbourne, Australia Department of Pediatrics, The University of Melbourne, Melbourne, Victoria, Australia Infectious Diseases, Department of General Medicine, Royal Children’s Hospital, Melbourne, Victoria, Australia
Nigel Crawford
Affiliation:
Surveillance of Adverse Events Following Vaccination in the Community (SAEFVIC), Murdoch Children’s Research Institute, Melbourne, Victoria, Australia COVID-19 Response, Department of Health Victoria, Melbourne, Australia Department of Pediatrics, The University of Melbourne, Melbourne, Victoria, Australia Infectious Diseases, Department of General Medicine, Royal Children’s Hospital, Melbourne, Victoria, Australia
*
Corresponding author: Hazel J. Clothier; Email: hazelc@unimelb.edu.au
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Abstract

Safe vaccines are critical for biosecurity protection, yet adverse events—rightly or wrongly attributed to immunization—potentially cause rapid loss of confidence, reduced vaccine uptake, and resurgence of preventable disease. Effective vaccine safety incident management is essential to provide assessment and lead appropriate actions to ensure vaccination programs are safe and mitigate unwarranted crisis escalation that could damage vaccine programs and the effective control of vaccine preventable disease outbreaks or pandemics. Incident management systems (IMS) are used globally to direct emergency management response, particularly for natural disasters of fire, flood, and storm. Public health is equally an emergency response and can therefore benefit from these command control constructs. While examples of IMS for outbreak response and mass immunization logistics exist, there is little to no information on their use in vaccine safety. We describe Australia’s vaccine safety Alert Advisory Group establishment in Victoria during the COVID-19 pandemic and onward embedding into routine practice, anticipant of new vaccines, and the next biosecurity threat.

Type
Brief Report
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Society for Disaster Medicine and Public Health, Inc

Safe vaccines are critical for biosecurity protection with adverse events, rightly or wrongly attributed to immunization, potentially causing rapid loss of confidence, reduced vaccine uptake, and diminished ability to effectively manage biosecurity threats.Reference Danchin and Buttery1 COVID-19 vaccination was rightly planned as high-volume rapid delivery programs to combat the pandemic.Reference Kashte, Gulbake and El-Amin2 Such new vaccine implementations at scale inevitably bring challenges demanding preprepared capability to take action to ensure safety and maintain confidence in immunization.

Incident management systems (IMS) are used globally to direct emergency management response, particularly for natural disasters of fire, flood, and storm.3, Reference Burgiel4 Public health is equally an emergency response and can therefore benefit from these command control constructs.Reference Awan, Clark-Ginsberg and Fisher5

The Department of Health of Australia’s second largest state, Victoria (population approximately 6.5 million),6 in anticipation of a COVID-19 pandemic vaccine, established a structured escalation pathway called an “Alert Advisory Group” (AAG) modeled on Australia’s emergency interservice incident management system (AIIMS).3 This ensured the state was primed to rapidly respond to safety challenges, provide assessment, lead actions to ensure program safety, and mitigate unwarranted crisis escalation that could damage the vaccination response critical to halt the pandemic.

We describe the vaccine safety AAG incident management structure, its use during the pandemic, and onward embedding into routine practice, anticipant of new vaccines and the next biosecurity threat.

Victoria’s Vaccine Safety Surveillance Landscape

Victoria has comprehensive robust vaccine safety services through Surveillance of Adverse Events Following Vaccination in the Community (SAEFVIC), established in 2007.Reference Clothier, Crawford and Kempe7, Reference Clothier, Crawford and Russell8 SAEFVIC provides intelligence informing national program policy with integrated clinical services for review of serious adverse events and clinical advice to individuals. During COVID, these clinical services were expanded to a state-wide network of specialist immunization services (VicSIS clinics) for both adult and pediatric vaccinees.Reference Gordon, Virah Sawmy and Duckworth9

SAEFVIC surveillance comprises multifaceted data interrogation systems to effectively detect, validate, and investigate vaccine safety signals.Reference Clothier, Crawford and Russell8, Reference Buttery and Clothier10, Reference Laemmle-Ruff, Lewis and Clothier11 The state-level system partners with the national AusVaxSafety post vaccination active surveillance survey that supports vaccinees from participating sites to report adverse events via automated responses on days 3, 8, and 42 post-vaccination.Reference Deng, Glover and Dymock12 This integrated program of surveillance provides assurance that vaccines are as safe as possible; however, inevitably alerts or challenges will arise, real or spurious. To maintain confidence in immunization, it is important that these challenges can be rigorously and transparently addressed.Reference Danchin and Buttery1, Reference Lun, Ning and Wang13

Methods

Alert Advisory Group (AAG) Structure

The AAG comprises four foundation role-responsibility pillars representing key stakeholders across actionable themes: clinical, epidemiology, policy, and communications (Figure 1). The roles were not designated to individuals but purposely maintained as expertise-based with a cascading roster to ensure each domain could be consistently represented. The AAG was not an alternative to clinical care or a causality assessment but was tasked to provide rapid assessment of the safety concern, determine the real or perceived risk to the vaccination program and/or risk of consequent vaccine hesitancy in the community, and initiate mitigation strategies as required.

Figure 1. The four-pillar structure of Victoria’s Alert Advisory Group.

Terms of reference were purposed to ensure (1) department oversight of vaccine safety incident and management, (2) subject matter expertise for informed decision-making, (3) informed stakeholders, (4) identify and mitigate spurious alerts from causing unwarranted alarm, and (5) documentation of process and action outcomes.

Terms of reference were approved by June 2020 in anticipation of the COVID-19 vaccine rollout, which in Australia commenced 8 months later, in February 2021. The aim was to coordinate and not duplicate, particularly as other jurisdictions around Australia established similar processes during the COVID-19 pandemic, with the national regulator (TGA) a standing invite to all AAGs and weekly information sharing via TGA-convened virtual meetings, thus maintaining state and national visibility across vaccine safety concerns. All AAGs were in confidence, with standard confidentiality agreements in place.

Triggers and Activation

An alert was broadly defined as any issue that could cause risk of harm to individuals or confidence in immunization programs. This was intentionally broad to be inclusive and best prepared for the unknown.

Alert triggers were anticipated to arise through international networks, existing surveillance systems intended to capture reports of serious adverse events following immunization (AEFI), surveillance signal detections, and media (including social media).Reference Islam, Kamal and Kabir14 While any cause for concern could trigger an AAG, 5 specific events were predefined: (1) an acute clinical event leading to an intensive care unit admission, life threat, or death, (2) a significant increase in reporting trend above background rate expectation, (3) a media story generating attention that may damage the program, (4) a national or international AEFI issue of concern, and (5) cold chain breach or vaccination error (with vaccine administered to multiple people).

An AAG could be activated by a representative of any one of the four pillars and, during the COVID response, was facilitated by a single point of contact (dubbed “the bat phone”) at the Victorian Vaccine Control Centre (VVCC). On receiving a call, the VVCC would schedule an AAG accessing a rostered contact list to ensure each role was appropriately filled and the AAG convened in a timely manner.

AAG Activations

The first AAG activation occurred 3 weeks into the COVID-19 vaccination program for a serious AEFI, which, on review, was considered not associated with vaccination and de-escalated. Shortly thereafter, on March 18, 2021, the second AAG was convened as concerns were raised internationally of blood clots following AstraZeneca vaccination, with European Medical Agency (EMA) and Australian Technical Advisory Group for Immunisation (ATAGI) statements released on March 19, 2021.15, 16

From February 2021 to November 2023, Victoria convened 73 AAGs (54 in the first 12 months, 71 (97%) related to COVID-19 vaccines). Review of reasons for AAG activation provides insight to the safety challenges arising. Most common (n=51, 70%) were individual serious AEFI followed by 10 (14%) vaccination error events, 8 (11%) potential safety signals, 3 each for media rumors and international scares, and 1 AAG considered abusive behavior toward immunization staff and the impact on their psychological well-being (Figure 2).

Figure 2. Alert Advisory Group meetings by topic, month and year, Victoria 2021–Nov 2023.

Reason for convening AAGs changed over time as the COVID-19 vaccination program matured. The first 3 months were mostly individual serious AEFI—at that time any death triggered an AAG, and as the program initially focused on aged care facilities this was not an uncommon coincidental event.Reference Clothier, Mesfin and Strange17 In addition, this period included the first local cases of thrombosis with thrombocytopenia syndrome (TTS).Reference Hocking, Chunilal and Chen18 The next 6 months were mixed, with surveillance trend triggers, in particular myocarditis and pericarditisReference Cheng, Clothier and Morgan19 (June 10, 2021 AAG), and rumors, including malicious social media hoaxes fabricating death of 2 youth.Reference Davey20 From 2022 onward, AAGs mostly responded to individual unusual serious AEFI that were not listed in product information and large-scale vaccination error events, with frequency declining to approximately bimonthly (Figure 2).

The one AAG convened to address increasing abuse experienced by immunization staff from persons demanding access to specific vaccine brands (which, at that time, were restricted to target groups as a means to manage limited supply) demonstrates the flexibility of AAGs to address varied vaccine safety challenges.

De-escalations and Escalations

A key AAG objective was to determine risk and initial steps for mitigation, loosely as a binary response of de-escalate or escalate. De-escalations primarily comprised media holding lines in readiness to respond to community concern if they arose. Escalations saw formation of incident management team (IMT), with the four pillars of the AAG forming the base IMT structure with additional stakeholders and subject matter experts brought in as appropriate.

Specific IMTs were established for ongoing review and management of TTS, myocarditis and pericarditis, and two vaccination administration error events involving over 1000 and 600 vaccine recipients, respectively.

One example of an AAG escalation was in response to a large-scale vaccine error event, whereby vaccine had been administered past its use-by thaw date, impacting over 600 vaccinations. Thaw expiry dates were a specific complexity for mRNA vaccines because vaccines originally stored at -70 degrees Celsius could be thawed and kept at +2 to +8 Celsius in standard vaccine refrigerators for up to 28 days prior to use, requiring diligent record keeping and checking of dates.21 In this incident, the timing from thaw to use was not in question; therefore, there was minimal increased risk of adverse events, but rather the efficacy of vaccine administered could not be assured, as storage was outside of the manufacturer’s requirements.21 A series of IMTs were held, with a broad range of stakeholders including community representation, to lead the process of open disclosure to those potentially impacted22 and determine vaccination pathways and track activities through to closure of the event. The structured IMTs facilitated capture of lessons learned. These were incorporated into vaccination error guidelines adopted nationally,23 vaccine error document templates, and an online eLearning module (available through the Melbourne Vaccination Education Centre (MVEC)) on vaccine error prevention, management, and open disclosure.24

Business As Usual

Victoria’s AAG process demonstrated good planning and preparedness, flexibility to different triggers and reasons for an alert, and provided responsive and timely escalation and coordinated communication. AAGs ensured a supportive environment for reporting and escalating incidents, facilitated a direct link between clinicians and vaccine safety public health teams, provided effective incident management, and directed long-term outcomes to improve safety. These attributes were considered as key lessons learned and, therefore, the AAG was embedded into routine vaccine safety surveillance systems.Reference Laemmle-Ruff, Lewis and Clothier11 With the VVCC disbanded following the peak of the COVID-19 crisis, central coordination was transferred to SAEFVIC as Victoria’s Vaccine Safety Surveillance Service in mid-2023, in partnership with the Department of Health, maintaining the four-pillar role profiles. Following this transfer of coordination, AAGs have been convened for serious AEFI and vaccine error events, including one, on request, supporting another jurisdiction with large-scale vaccination error events.Reference Dunlevie25 Two AAGs have been held for vaccines other than COVID-19; one each for a serious AEFI and a vaccine error event.

Discussion

Incident management systems for civilian emergency response were developed in the 1970’s in response to communication breakdowns and inefficient coordination in the management of large wildfire events.Reference Hawkins, Ma and Pickett26 In the United States, incident control systems are part of the National Response Framework that provides guidance for national responses to all types of disasters and emergencies.Reference Burgiel4 In Australia—and especially Victoria as a high bushfire-risk state—these concepts are ensconced in the Australasian Inter-Service Incident Management System (AIIMS), providing the operational backbone of the Emergency Services State Control Centre.3, 27 Threats to public health are deemed a Class 2 emergency and, as such, fall under the same emergency management constructs.Reference Awan, Clark-Ginsberg and Fisher5, 28 However, there is a dearth of literature on how AIIMS has been applied in the infectious disease control setting. One exception is the clear articulation of the value of incident control for outbreak response “after action reviews,” particularly during the COVID-19 outbreak response by Dalton et al.Reference Dalton, Kirk and Durrheim29 The benefits of a coordinated response with clear leadership go beyond management of the incident itself but also to the protection of the mental well-being of the response personnel. While there are international examples of incident management used for logistics of mass vaccination campaigns,Reference Phillips and Williamson30, Reference Sara, Sara and Gavin31 this article is, to the authors’ best knowledge, the first description of IMS used for vaccine safety signal events in either a pandemic or routine setting.

The flexibility and simplicity of the IMS’s adaptability to different crisis settings is both commendable and a sound recognition of the intent.Reference Hawkins, Ma and Pickett26 The robust processes are complimentary to support future rapid deployment intended by the global Mission for 100 Day Vaccines for biosecurity threats.32 Likewise, these processes anticipate new vaccines, such as respiratory syncytial virus vaccine, that will target important populations, including pregnant women and the elderly.Reference Anderson, Dormitzer and Nokes33 As clinical trials are logistically and economically limited in sample size and population heterogeneity,Reference Black34 the necessity for postmarketing surveillance systems to have capability not only to detect rare adverse events but also effectively respond to vaccine safety challenges is ever more the future for which we must prepare.Reference Black, Chandler and Edwards35

Conclusion

Victoria’s AAG escalation strategy using emergency incident management structures ensures a robust and well-prepared vaccination program able to rapidly assess and respond appropriately to escalate or de-escalate emergent vaccine safety challenges. This structure helped maintain confidence in the COVID-vaccine pandemic response and establish a framework for future vaccine safety challenges to biosecurity management.

Acknowledgments

The authors would like to acknowledge the Victorian Department of Health COVID-19 response teams and SAEFVIC and MVEC staff for their work in supporting vaccine safety in Victoria. We especially acknowledge both the state Victoria Vaccine Control Centre and National Vaccine Operations Centre for the secretarial coordination of AAGs throughout the pandemic response. Thank you also to our VicSIS, AusVaxSafety, and Global Vaccine Data Network colleagues. SAEFVIC at the Murdoch Childrens Research Institute is supported by funding from the Department of Health Victoria.

Author contribution

Concept, design, and establishment of AAGs: HC, MW, JB, NC. Incident Management leadership: HC, MW, JB, NW. Data management and analysis: HC. Evaluation and embedding into routine practice: all authors. Writing of the manuscript: HC. Review and editing of the manuscript: all authors.

Competing interest

The authors have no conflicts of interest to declare.

References

Danchin, M, Buttery, J. COVID-19 vaccine hesitancy: a unique set of challenges. Intern Med J. Dec 2021;51(12):19871989. doi:10.1111/imj.15599CrossRefGoogle ScholarPubMed
Kashte, S, Gulbake, A, El-Amin, SF Iii, et al. COVID-19 vaccines: rapid development, implications, challenges and future prospects. Human Cell. 2021/05/01 2021;34(3):711733. doi:10.1007/s13577-021-00512-4CrossRefGoogle ScholarPubMed
National Council for Fire and Emergency Services. Australiasian Inter-Service Incident Management System. AFAC. Accessed December 27, 2023. https://www.afac.com.au/initiative/aiimsGoogle Scholar
Burgiel, SW. The incident command system: a framework for rapid response to biological invasion. Biological Invasions. 2020/01/01 2020;22(1):155165. doi:10.1007/s10530-019-02150-2CrossRefGoogle Scholar
Awan, J, Clark-Ginsberg, A, Fisher, H, et al. Conceptual Framework for Understanding Incident Management Systems During Public Health Emergencies. Disaster Medicine and Public Health Preparedness. 2023;17:e158. e158. doi:10.1017/dmp.2022.77Google Scholar
Australian Bureau of Statistics. Snapshot of Victoria: High level summary of data for Victoria in 2021. Australian Bureau of Statistics. Accessed December 27, 2023. https://www.abs.gov.au/articles/snapshot-vic-2021Google Scholar
Clothier, HJ, Crawford, NW, Kempe, A, et al. Surveillance of adverse events following immunisation: the model of SAEFVIC, Victoria. Commun Dis Intell Q Rep. Dec 2011;35(4):294–8.Google ScholarPubMed
Clothier, HJ, Crawford, NW, Russell, M, et al. Evaluation of ’SAEFVIC’, A Pharmacovigilance Surveillance Scheme for the Spontaneous Reporting of Adverse Events Following Immunisation in Victoria, Australia. Drug Saf. Jun 2017;40(6):483495. doi:10.1007/s40264-017-0520-7CrossRefGoogle ScholarPubMed
Gordon, SF, Virah Sawmy, E, Duckworth, E, et al. Victorian Specialist Immunisation Services (VicSIS) - bolstering adult clinics for COVID-19 vaccines. Hum Vaccin Immunother. Nov 30 2022;18(5):2052701. doi:10.1080/21645515.2022.2052701CrossRefGoogle ScholarPubMed
Buttery, JP, Clothier, H. Information systems for vaccine safety surveillance. Hum Vaccin Immunother. Nov 30 2022;18(6):2100173. doi:10.1080/21645515.2022.2100173CrossRefGoogle ScholarPubMed
Laemmle-Ruff, I, Lewis, G, Clothier, HJ, et al. Vaccine safety in Australia during the COVID-19 pandemic: lessons learned on the frontline. Front Public Health. 2022;10:1053637. doi:10.3389/fpubh.2022.1053637CrossRefGoogle ScholarPubMed
Deng, L, Glover, C, Dymock, M, et al. The short term safety of COVID-19 vaccines in Australia: AusVaxSafety active surveillance, February - August 2021. Med J Aust. Aug 15 2022;217(4):195202. doi:10.5694/mja2.51619CrossRefGoogle ScholarPubMed
Lun, P, Ning, K, Wang, Y, et al. COVID-19 Vaccination willingness and reasons for vaccine refusal. JAMA Netw Open. Oct 2 2023;6(10):e2337909. doi:10.1001/jamanetworkopen.2023.37909CrossRefGoogle ScholarPubMed
Islam, MS, Kamal, AM, Kabir, A, et al. COVID-19 vaccine rumors and conspiracy theories: the need for cognitive inoculation against misinformation to improve vaccine adherence. PLoS One. 2021;16(5):e0251605. doi:10.1371/journal.pone.0251605CrossRefGoogle ScholarPubMed
European Medicines Agency. COVID-19 Vaccine AstraZeneca: benefits still outweigh the risks despite possible link to rare blood clots with low blood platelets. EMA. 2021. Updated 19 March 2021. Accessed December 27, 2023. https://www.ema.europa.eu/en/news/covid-19-vaccine-astrazeneca-benefits-still-outweigh-risks-despite-possible-link-rare-blood-clots-low-blood-plateletsGoogle Scholar
Therapeutic Goods Administration. AstraZeneca ChAdOx1-S COVID-19 vaccine: no proven link with blood clots. Australian Government Department of Health and Aged Care. 2021. Accessed December 27, 2023. https://www.tga.gov.au/news/safety-alerts/astrazeneca-chadox1-s-covid-19-vaccine-no-proven-link-blood-clotsGoogle Scholar
Clothier, HJ, Mesfin, YM, Strange, S, et al. Background rates of hospital transfer and death in Australian aged care facilities: estimates to assist interpretation of rates after COVID-19 vaccination. Med J Aust. Aug 16 2021;215(4):180181. doi:10.5694/mja2.51170CrossRefGoogle ScholarPubMed
Hocking, J, Chunilal, SD, Chen, VM, et al. The first known case of vaccine-induced thrombotic thrombocytopenia in Australia. Med J Aust. Jul 2021;215(1):1920.e1. doi:10.5694/mja2.51135CrossRefGoogle ScholarPubMed
Cheng, DR, Clothier, HJ, Morgan, HJ, et al. Myocarditis and myopericarditis cases following COVID-19 mRNA vaccines administered to 12-17-year olds in Victoria, Australia. BMJ Paediatr Open. Jun 2022;6(1)doi:10.1136/bmjpo-2022-001472CrossRefGoogle ScholarPubMed
Davey, Melissa. Australia’s drug regulator received two hoax reports of children dying from Covid vaccines. The Guardian. 10 July 2023. Accessed December 27, 2023. https://www.theguardian.com/australia-news/2023/jul/10/tga-covid-vaccine-child-death-hoaxGoogle Scholar
Therapeutic Goods Administration. COVID-19 vaccine: Pfizer Australia - COMIRNATY (tozinameran) (mRNA). Australian Government Department of Health and Ageing. Updated 21 August 2023. Accessed December 27, 2023. https://www.tga.gov.au/covid-19-vaccine-pfizer-australia-comirnaty-tozinameran-mrnaGoogle Scholar
Australian Commission on Safety and Quality in Health Care. Australian Open Disclosure Framework. 2013. Accessed December 27, 2023. https://www.safetyandquality.gov.au/sites/default/files/migrated/Australian-Open-Disclosure-Framework-Feb-2014.pdfGoogle Scholar
Australian Technical Advisory Group on Immunisation. ATAGI clinical guidance on COVID-19 vaccine administration errors. Australian Government Department of Health and Aged Care. 2022. Updated 6 June 2023. Accessed December 27, 2023. https://www.health.gov.au/resources/publications/atagi-clinical-guidance-on-covid-19-vaccine-administration-errors?language=enGoogle Scholar
Melbourne Vaccination Education Centre. Vaccine Errors: prevention, management and open disclosure. Accessed December 27, 2023. https://education-mvec.mcri.edu.au/courses/vaccine-errors-prevention-management-and-open-disclosure/Google Scholar
Dunlevie, JL, A. 20 years of vaccinations compromised after Tasmanian medical clinic’s record-keeping fail. ABC News. 14 June 2023. Accessed December 27, 2023. https://www.abc.net.au/news/2023-06-14/vaccinations-tasmanian-clinic-compromised-record-keeping-fail/102477068Google Scholar
Hawkins, RM, Ma, KY, Pickett, AD, et al. Reimagining Incident Management Systems for public health responses. Health Security. 2023/09/01 2023;21(S1):S95S100. doi:10.1089/hs.2023.0037CrossRefGoogle ScholarPubMed
Victoria State Department. State Health Emergency Arrangements. Department of Health. Accessed December 27, 2023. https://www.health.vic.gov.au/emergencies/state-health-emergency-response-arrangementsGoogle Scholar
Dalton, CB, Kirk, MD, Durrheim, DN. Using after-action reviews of outbreaks to enhance public health responses: lessons for COVID-19. Med J Aust. Jan 17 2022;216(1):49. doi:10.5694/mja2.51289CrossRefGoogle ScholarPubMed
Phillips, FB, Williamson, JP. Local health department applies Incident Management System for successful mass influenza clinics. JPHMP. 2005;11(4):269273.Google ScholarPubMed
Sara, J, Sara, B, Gavin, G, et al. Lessons learnt from the applying the Centers for Disease Control and Prevention (CDC) evaluation framework to the measles incident managemtent system response, USA, 2020–2021. BMJ Global Health. 2023;8(3):e011861. doi:10.1136/bmjgh-2023-011861Google Scholar
Coalition for Epidemic Preparedness Innovations. Delivering Pandemic Vaccines in 100 Days: What will it take? 2022. Accessed December 27, 2023. https://cepi.net/wp-content/uploads/2022/11/CEPI-100-Days-Report-Digital-Version_29-11-22.pdf?swcfpc=1Google Scholar
Anderson, LJ, Dormitzer, PR, Nokes, DJ, et al. Strategic priorities for respiratory syncytial virus (RSV) vaccine development. Vaccine. Apr 18 2013;31 Suppl i(Suppl 2):B209-15. doi:10.1016/j.vaccine.2012.11.106Google ScholarPubMed
Black, S. The costs and effectiveness of large Phase III pre-licensure vaccine clinical trials. Expert Rev Vaccines. 2015;14(12):1543–8. doi:10.1586/14760584.2015.1091733CrossRefGoogle ScholarPubMed
Black, SB, Chandler, RE, Edwards, KM, et al. Assessing vaccine safety during a pandemic: recent experience and lessons learned for the future. Vaccine. Jun 7 2023;41(25):37903795. doi:10.1016/j.vaccine.2023.04.055CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. The four-pillar structure of Victoria’s Alert Advisory Group.

Figure 1

Figure 2. Alert Advisory Group meetings by topic, month and year, Victoria 2021–Nov 2023.