CHALLENGES IN GLOBAL DISTRIBUTION: Comparison
View Latest Version
Please note this is a comparison between Version 2 by Jason Zhu and Version 1 by Nengak Precious Danladi.

This sentudry is aimed at addressing th

CHALLENGES IN GLOBAL DISTRIBUTION AND EQUITABLE ACCESS TO MONKEYPOX VACCINESe Challenges in global Distribution and equitable access to monkeypox vaccines.

  • Monkeypox
  • Vaccines
  • Challenges
  • Equitable Distribution

Introduction

Caused by the MPOX Virus (MPXV), Monkeypox is a Zoonotic double-stranded DNA virus belonging to the Orthopoxvirus genus within the Poxviridae family. [1][2]. This viral family also includes the variola virus, the causative agent of smallpox, a disease eradicated over three decades ago following widespread immunization efforts using the closely related vaccinia virus (VACV) [3].MPOX was first recorded in humans in 1970 in the Democratic Republic of Congo (DRC). Since then, multiple cases have been reported across the tropical rainforest regions of Western and Central Africa [4]. However, the MPOX virus (MPXV) outbreak has expanded beyond its traditional endemic regions in Central and West Africa, spreading to multiple non-endemic countries across Europe, the Americas, and other parts of the world [2][4]. Five notable MPOX outbreaks have been documented, occurring in 1970, 1996–1997, 2003, and 2018 [3][5][6][7][8][9]. Between January 2022 and August 2024, more than 120 countries have documented MPOX cases, with over 100,000 confirmed cases in laboratories and more than 220 fatalities reported among these confirmed cases [2][9].

In the USA, 71 individuals were infected in 2003, with laboratory confirmation in 35 cases, due to contact between prairie dogs and African rodents. From 2018 to 2021, the UK reported seven MPOX cases, four linked to travel from regions where the disease is prevalent[10][11][12]. In July 2021, two people returning from Nigeria were diagnosed with MPOX in Texas and Maryland, USA[2][13][14]. Due to the rapid global spread of the virus, primarily fueled by international travel and mobility, the World Health Organization (WHO) designated MPOX (MPXV) as a Public Health Emergency of International Concern (PHEIC) under the International Health Regulations[15]. On August 14, 2024, the WHO Director-General officially declared the MPOX outbreak a public health emergency, highlighting the rapid spread of the disease, the growing number of cases globally, and the urgent need for coordinated international efforts to control its transmission[16].

Over the years, vaccines have proven effective in infectious disease control and prevention. The same applies to MPOX[17][18]. Given the close relationship between the two viruses, existing vaccines, such as the smallpox vaccine, have shown efficacy in preventing MPOX infections[9][18]. However, the global response to the MPOX outbreak has exposed deep-seated challenges in the distribution and equitable vaccine access[18][19]. Factors such as vaccine hoarding, lack of manufacturing capacity in LMICs, logistical barriers, and intellectual property issues hinder equitable distribution[17][18]. This research examines the global challenges in distributing and ensuring equitable access to MPOX vaccines. In doing so, it seeks to contribute to ongoing efforts to achieve equitable health outcomes in the global fight against emerging infectious diseases.

 

MONKEYPOX VACCINES

Immunological reactions to a single Orthopox virus can recognize other Orthopox viruses and provide variable degrees of protection based on the similarity between the different Orthopox viruses. The viruses variola, vaccinia, and monkeypox (pox) are classified under the genus Orthopoxvirus. Because of shared antigens, vaccination can effectively prevent both variola and monkeypox. Recent research has demonstrated that the vaccinia vaccine, previously known for its efficacy in preventing smallpox, can also protect against the MPOX virus[5][20][21][22][23][24].

This immunological cross-reactivity has facilitated the development of several animal models of smallpox infection, which have been utilized to evaluate the effectiveness of vaccinations and antivirals[25]. This cross-reactivity is mainly due to two factors. Firstly, the Orthopox viruses exhibit a significant level of sequence similarity, particularly in immunologically essential proteins, resulting in a substantial number of common immune epitopes[26][27]. Additionally, the reaction included a broad range of antibodies that specifically targeted a minimum of 24 membrane and structural proteins[28][29][30]. Similarly, T-cell responses detect epitopes in a broad range of viral proteins, with CD4 T cells showing a preference for recognizing structural proteins[31]. While CD8 T cells specifically target proteins that are encoded early in the viral life cycle, such as virulence factors[32][33]. A neutralizing antibody was established to protect against smallpox (produced by the variola virus) in humans and against other Orthopox viruses in animal models[34]. Although T cells are not essential for protection, they contribute to viral clearance.

Some of the first evidence that vaccinia-specific immune responses can protect against MPOX comes from investigations done in the 1980s. Three studies were done on chimpanzees, rhesus macaques, and cynomolgus macaques to determine the efficacy of smallpox vaccines against the MPOX virus using the Dryvax vaccine (first-generation smallpox vaccine). The result showed that almost all vaccinated animals were protected against the virus. The one exception to the above results was determined to have not responded to the vaccine. Although these studies were small, they suggested that smallpox vaccines offered some protection from the MPOX virus. This laid the groundwork for understanding the cross-protective immunity between smallpox and MPOX and has a massive role in vaccine development and public health strategies[35]. The relationship between the rise in MPOX cases following the end of smallpox vaccination and a growing population with limited immune exposure has been hypothesized and associated with a growing population with limited immune exposure. Due to concerns about bioterrorism and increasing outbreaks of the MPOX virus, the WHO continued to license the smallpox vaccines[36][37]. The smallpox vaccines are classified according to generation.

First-generation smallpox vaccines were used to eradicate smallpox. They contained live vaccine viruses and were administered through bifurcated needles. Historically, patients with a characteristic pustule were protected against the virus. These vaccines, which include Dryvax®, APSV®, Lancy–Vaxina®, and L-IVP®, were last produced in the early 1980s. Rare but potentially life-threatening complications, such as post-vaccinal encephalitis, progressive vaccinia, and myopericarditis, mainly occurred in immunocompromised patients[35][36][37][38][39]. Dryvax, a first-generation smallpox vaccine developed by Wyeth Laboratories, consisting of the New York City Board of Health (NYCBH) strain of vaccinia, the Lister/Elstree and the Ikeda vaccinia virus strains, which were lymph derived and cultivated on the skin of animals[37]. Routine use of this vaccine ended in the United States in 1972, the license for Dryvax was revoked in 2008, and no supply of this vaccine remains[21]. The second-generation smallpox vaccines contained replication-competent viruses produced in a controlled laboratory setting. The focus was eliciting a similar immune response to the first generation while curbing adverse side effects[35][36][37][38][39]. The third generation of smallpox vaccines concentrated on attenuated vaccine strains such as LC16m8, MVA, NYVAC, and dVVL to improve the safety profile[38].

The United States (US) has authorized second—and third-generation smallpox vaccines for vaccination. Cell culture methods were utilized for their development to enhance the safety traits of these vaccines. In 2007, the US Food and Drug Administration licensed ACAM2000. It is generated from a clone of Dryvax. Originating from Emergent Bio Solutions, this vaccine is specifically designed for active vaccination against smallpox, excluding MPOX disease, in those with a high risk for smallpox virus infection[40][41]. While the efficacy of ACAM2000 in preventing MPOX has not been definitively shown, several studies have verified a certain level of immunogenicity. Additionally, one research demonstrated protection against this virus by employing its first-generation progenitor, Dryvax[42][43]. Although the United States has a large stock of ACAM2000, this vaccine exhibits more adverse events and contraindications than the third-generation [40]. The adverse effects associated with this vaccine injection included pain and swelling at the injection site, fatigue, and muscular discomfort in about 50% of the recipients. Additionally, 20-40% of the recipients experienced lymphadenopathy and headache, while around 20% had fever. About 20% of the recipients reported joint pain, backache, gastrointestinal pain, or nausea. More severe adverse effects encompass widespread vaccinia, eczema vaccinatum, progressive vaccinia, post-vaccinial encephalopathy or encephalitis, and mortality. This vaccine was contraindicated to individuals with severely compromised immune systems, pregnant women or lactating mothers, those with cardiac disease or cardiac risk factors, individuals with active eczema, and infants under 12 months of age[37][44][45][46]. Additional vaccines based on the vaccinia virus were created by subjecting the virus to repeated passage in primary cell culture or eggs to attenuate[37].

In 2019, the FDA approved JYNNEOS, a third-generation smallpox vaccine. [41] It is a product of the Modified Vaccinia Ankara (MVA) attenuated strain, created through more than 500 serial passages of the vaccinia virus Ankara strain in chick embryo fibroblast cells. It is purified using tangential flow filtration and supplied as a frozen-liquid suspension[36][43]. The vaccine is administered subcutaneously in two doses, 28 days apart, usually in the upper arm. JYNNEOS can also be administered intradermally, though this method is not recommended for individuals with weakened immune systems or a history of keloid scarring and is not preferred as the initial dose for post-exposure vaccination[47]. After two doses, the immune response is comparable to that of ACAM2000 but with fewer side effects[34][48]. MVA-based vaccines do not produce the typical skin reaction. Still, common mild side effects include pain at the injection site (85% of recipients), redness, swelling, itching, and induration at the injection site (40–60%), as well as fatigue, muscle aches, headaches (20–40%), nausea (17%), and chills (10%). Fever is uncommon and observed in about 2% of recipients; cardiac events were reported in about 2%, with no cases of myopericarditis[34]. The Vaccine approval for the protection of smallpox in adults came from the European Medicines Agency (EMA) in 2013 under the trade name IMVANEX and under the trade name IMVAMUNE by the Public Health Agency of Canada (PHAC) in the same year. In 2020, PHAC expanded IMVAMUNE's use to include MPOX and other orthopoxvirus infections, and in July 2022, EMA similarly extended IMVANEX's use to cover monkeypox and vaccinia-related diseases[49].

LC16m8 is another third-generation vaccine developed from the Lister strain used in first-generation vaccines. Through multiple tissue culture passages and selection for an attenuated phenotype, the LC16m8 strain was produced, which lacks a full-length, functional B5 membrane protein[34]. The vaccine is produced in cell culture using rabbit kidney cells and has been licensed since 1975 for active smallpox vaccination in Japan. In August 2022, Japan expanded the vaccine's use to include protection against MPOX. Due to their attenuated nature, these vaccines have a better safety profile and can be given to immunocompromised individuals. The effectiveness of these vaccines against MPOX is inferred from animal studies showing protection against the MPOX virus in non-human primates vaccinated with these vaccines, as well as clinical trials that demonstrated their immunogenicity in humans[37].

These vaccines can be used in pre-exposure to prevent infection and illness or post-exposure to mitigate infection and disease. Pre-exposure vaccination is recommended for individuals at the highest risk, with second or third-generation vaccines providing the most effective protection. Post-exposure vaccination is ideally administered within four days of exposure to prevent infection. However, it can still be given up to 14 days after exposure to lessen the severity of the disease. Second or third-generation vaccines are also preferred for post-exposure vaccination. In July 2022, authorities in Montreal, QC, Canada, administered at least 3000 doses[34]. In all cases, healthcare professionals should know who may qualify for vaccination so they can consult national health authorities about accessing vaccines from national stockpiles. Smallpox vaccines are not available commercially or privately.

 

CHALLENGES IN GLOBAL DISTRIBUTION OF MONKEYPOX VACCINES

The World Health Organization (WHO) has drawn attention to global competition for Mpox vaccines, with 35 countries vying for access to the 16.4 million currently available doses[50]. There is a growing concern that low-income countries may encounter challenges securing the vaccine[51]. Most notably, many African countries where Mpox has been prevalent for decades have yet to receive a single dose of the vaccine. Wealthier nations have obtained most of the available doses, limiting options for other affected countries, particularly those in Africa[51][52].

AIDS, COVID-19, and the current monkeypox outbreak are evidence of inequities in Global Health strategy. It can be observed that Global health strategies for disease burden control are only put in place when the Global North is affected[3]. The concentration of global vaccine production in the Global North, with numerous vaccine production facilities in the United States, Japan, and Europe, has led to a reliance on vaccine supply from these regions. This reliance creates significant inequity in global vaccine coverage and insufficient domestic production, particularly in Africa[53]. Despite establishing vaccine production facilities by foreign pharmaceutical industries across Africa[54] It still produces less than 1% of all vaccines used on the continent[55].

Additional challenges, such as the lack of qualified personnel, specialized vaccine development and manufacturing infrastructure, inadequate training, ineffective awareness campaigns, and difficulties collecting and processing critical immunization data, further complicate the situation[51].

Furthermore, challenges such as unstable electricity supply and inadequate cold chain facilities could significantly impede comprehensive vaccine manufacturing in Africa[51].

 

 

BARRIERS TO EQUITABLE ACCESS TO MONKEYPOX VACCINES

Advance Purchase Agreements: High-income countries have leveraged advance purchase agreements (APAs) to secure priority access to newly produced vaccines. These agreements allow wealthier nations to stockpile vaccines, often at the expense of countries that may be more affected by monkeypox. This practice not only limits the availability of vaccines for lower-income nations but also reinforces inequities, as those countries cannot compete financially in the vaccine market. A more equitable approach would involve manufacturers setting aside a portion of their vaccine supply for global distribution, ensuring that all countries have access regardless of economic status[56]

Vaccine Stockpiling Reluctance: Nations with large stockpiles of vaccines are often hesitant to share these resources. This reluctance stems from concerns about maintaining sufficient supplies for their populations amid outbreaks. However, this hoarding behavior exacerbates global disparities in vaccine access, particularly affecting historically endemic countries that experience the highest case-fatality rates. To address this issue, countries should commit to contributing a portion of their stockpiled vaccines to an international distribution network, aligning their actions with global health commitments, and fostering collective security against outbreaks[56].

Lack of Organized Mechanisms for Low-Income Countries: Many low-income nations lack the infrastructure and financial means to procure vaccines independently, relying instead on international aid and charity. This dependency can lead to inconsistent access and delays in vaccination efforts, ultimately allowing the disease to spread unchecked. Establishing a coordinated global procurement and distribution system could help bridge this gap. Like the successful Revolving Fund for Access to Vaccines in the Americas, such a system would provide a structured approach for low-income countries to secure necessary vaccines, ensuring they are not left behind during public health emergencies[56].

Vaccine Nationalism: During health crises, many countries prioritize securing vaccines for their populations, a practice often called vaccine nationalism. This trend was evident during past outbreaks, such as H1N1 and COVID-19, where wealthier nations quickly acquired the majority of available doses, leaving lower-income countries with limited access. The current landscape for monkeypox is no different, as high-income countries have disproportionately secured vaccine supplies, creating a significant gap in availability for those most affected. To combat this, international frameworks and agreements are needed to promote fair distribution practices and discourage hoarding[56][57].

Inequitable Distribution of Existing Resources: Even when vaccines are available, their distribution is often inequitable. Many countries with high monkeypox prevalence receive little to no doses, while nations with minimal cases secure large quantities. This disconnect between disease burden and vaccine access is unjust and highlights a critical need for allocation strategies prioritizing regions most in need. Developing criteria based on case severity and potential risk factors can help guide equitable distribution[56].

Insufficient Surveillance and Reporting Mechanisms: Countries lacking robust health surveillance systems often face challenges in accurately documenting monkeypox cases. This limitation can lead to underreporting, resulting in these countries receiving fewer vaccines due to perceived lower needs. To address this, international support is crucial for building surveillance capacity in vulnerable nations. Enhanced data collection and reporting will improve vaccine allocation decisions and help contain future outbreaks effectively[56].

 

STRATEGIES TO IMPROVE GLOBAL DISTRIBUTION AND ACCESS

The global distribution of the monkeypox vaccine has faced many challenges, especially in ensuring equitable distribution and access for vulnerable populations. It can be improved through

Enhancing Global Health Policies, Establishing a New Public Health Structure, [58] Global Health Financing, [59] Addressing Pharmaceutical Monopolies, [58] Price Transparency, (60) Enhancing vaccine confidence and uptake, Utilizing social media for communication, [60] Implementing ring vaccination strategies, [61]

and International Cooperation and Solidarity[16]

 

RECOMMENDATIONS

Strengthening Global Vaccine Manufacturing Capacity

Significant disparities in fair access to necessary medical countermeasures, such as vaccines, were brought to light by the COVID-19 pandemic. Manufacturing capacity for pandemic vaccines is concentrated in too few countries. Eight of every ten vaccination doses produced has gone to high-income countries[62]. Expanding manufacturing capacity across different regions is crucial to overcoming supply constraints, particularly in low—and middle-income countries (LMICs). This could involve transferring technology to these regions, fostering partnerships between pharmaceutical companies and local producers, and encouraging cooperation between players from the public sector, business sector, academic institutions, and civil society.

Targeting countries with elevated risk profiles and limited access to resources

Nigeria, Ghana, and Cameroon have recorded about 15% of global monkeypox fatalities since 2022 but have fewer than 1% of the total cases worldwide[63].  Countries should be prioritized based on ethical principles. This prioritization could specify the order in which countries receive required doses or how large a share they receive from a given tranche. Under either method, historically endemic countries should receive the highest priority for monkeypox vaccines. After that, priority should be determined using countries’ projected cases and severity of outcomes[64]. Vaccine distribution should prioritize regions experiencing the highest incidence of monkeypox and populations at higher risk.

Overcoming Vaccine Nationalism through platforms like COVAX

Platforms such as COVAX (COVID-19 Vaccines Global Access) could be adapted to include monkeypox vaccines, ensuring a more coordinated global response. Establishing an international task force similar to ACT-Accelerator, used during COVID-19, could facilitate the distribution of monkeypox vaccines to the most vulnerable populations. COVAX was designed as an end-to-end coordination mechanism encompassing research and development and manufacturing, policy guidance, vaccine portfolio development, regulatory systems, supply allocation and country readiness assessments, transport logistics, vaccine storage and administration, and monitoring country coverage and absorption rates. It significantly contributed to alleviating the suffering caused by COVID-19 in the Global South. Today, the initiative has supplied 74% of all COVID-19 vaccine doses provided to low-income countries (LICs) during the pandemic. 52 92 AMC-eligible economies relied on COVAX for over half of their COVID-19 vaccine supply[65].

Strengthening Health Surveillance Systems.

A significant contributor to vaccine access inequities, especially in low and middle-income countries, is the underreporting of Mpox cases, especially in the Central and West African regions[58]. This is mainly attributable to the weak health surveillance systems in rural areas, which prevent early detection of cases, leading to underreporting cases. Due to this, the disease's hotspots may not be readily identified early, consequently preventing vaccines from being allocated to such areas. To address this issue, we recommend strengthening health surveillance systems in these regions by providing early warning systems incorporating robust data collection and sharing mechanisms. This will help prompt the detection and identification of cases in this region. In addition, assisting financially and technically to the end of developing disease monitoring and reporting systems, especially in low and middle-income countries, will help improve vaccine access and equity[58].

She was addressing Vaccine hesitancy.

A key challenge in the equitable distribution of Mpox vaccines is the unwillingness of people to receive these vaccines despite their availability. This is especially common in the Global South due to a lack of awareness, misinformation, or both[51]. Addressing vaccine hesitancy by healthcare workers, community leaders, and local influencers is paramount. This can be achieved via well-planned public health campaigns and community engagement aimed at adequately informing and sensitizing people about the importance of vaccines, debunking myths about vaccines, and encouraging at-risk populations to get vaccinated[66].

 

CONCLUSION

As the world continues to grapple with the Mpox epidemic, with some countries being significantly affected than others, there is an urgent need for a collaborative and progressive approach towards ensuring that countermeasures are not only provided but also fairly and equitably distributed to affected countries. Overcoming the challenges facing global distribution and equitable access to MPox vaccine through measures such as strengthening global vaccine manufacturing capacity, overcoming Vaccine Nationalism through platforms like COVAX, and addressing vaccine hesitancy are crucial steps in the fight against the Mpox epidemic.

References

  1. Jun Wang; Shahed- Ai- Mahmud; Angelo Chen; Kan Li; Haozhou Tan; Ryan Joyce; An Overview of Antivirals against Monkeypox Virus and Other Orthopoxviruses. J. Med. Chem.. 2023, 66, 4468-4490.
  2. Mpox. World Health Organization. Retrieved 2024-10-17
  3. Oriol Mitjà; Andrea Alemany; Michael Marks; Jezer I Lezama Mora; Juan Carlos Rodríguez-Aldama; Mayara Secco Torres Silva; Ever Arturo Corral Herrera; Brenda Crabtree-Ramirez; José Luis Blanco; Nicolo Girometti; Valentina Mazzotta; Aniruddha Hazra; Macarena Silva; Juan José Montenegro-Idrogo; Kelly Gebo; Jade Ghosn; María Fernanda Peña Vázquez; Eduardo Matos Prado; Uche Unigwe; Judit Villar-García; Noah Wald-Dickler; Jason Zucker; Roger Paredes; Alexandra Calmy; Laura Waters; Cristina Galvan-Casas; Sharon Walmsley; Chloe M Orkin; Viviana Leiro; Lucila Marchetta; Patricia Fernandez Pardal; María Inés Figueroa; Pedro Cahn; Katharina Grabmeier-Pfistershammer; Agnes Libois; Laurens Liesenborghs; Beatriz Grinsztejn; Mauro Schechter; Alberto dos Santos de Lemos; Alvaro Furtado Costa; Simone Queiroz Rocha; José Valdez Madruga; Darrell H. S. Tan; Sharmistha Mishra; Shreya Shah; Camila Jorquera; Alberto Castillo; Mauricio Carrión; Nelson Cevallos; Romain Palich; Valerie Pourcher; Emma Rubenstein; Pascal Migaud; Christoph Boesecke; Christian Hoffmann; Konstantinos Protopapas; Silvia Nozza; Anna Maria Cattelan; Cristina Mussini; Antonella D'Arminio Monforte; Raúl Adrian Cruz Flores; Edgar Pérez Barragán; Alma Leticia Rodríguez Guzmán; Dimie Ogoina; Nneka Marian Chika-Igwenyi; Onyeaghala Chizaram; Jenny Valverde López; Angelica García Tello; Maria Ubals; Martí Vall; Adrià Mendoza; Clara Suñer; Bonaventura Clotet; Jordi Bechini; Jose A Lepe; M. Dolores Navarro-Amuedo; Jose Ignacio Bernadino; Alba Català; Eloy José Tarín Vicente; Borja González Rodríguez; Sergi Rodriguez-Mercader; Francisca Sánchez-Martinez; Esperanza Cañas-Ruano; Laura Parra-Navarro; Finn Filén; Carmen Tallón de Lara; Dominique Braun; Vanja Piezzi; Michael Burkhard; Helen Kovari; Anja Mönch; Jake Dunning; Pedro Simoes; Achyuta Nori; Sarah Keegan; John P Thornhill; Vanessa Apea; Teymur Noori; Joyce L. Jones; Seth Judson; Elizabeth A. Gilliams; Matthew M. Hamill; Jeanne Keruly; Andrés F. Henao Martínez; Aung Lin; Jessica So; Kusha Davar; Diana Villareal; Miguel Tapia Paredes; Mpox in people with advanced HIV infection: a global case series. Lancet. 2023, 401, 939-949.
  4. 2022 Monkeypox outbreak global map : cases . Center for Disease Control. Retrieved 2024-10-17
  5. Eveline M. Bunge; Bernard Hoet; Liddy Chen; Florian Lienert; Heinz Weidenthaler; Lorraine R. Baer; Robert Steffen; The changing epidemiology of human monkeypox—A potential threat? A systematic review. PLOS Neglected Trop. Dis.. 2022, 16, e0010141.
  6. Emmanuel F. Alakunle; Malachy I. Okeke; Monkeypox virus: a neglected zoonotic pathogen spreads globally. Nat. Rev. Microbiol.. 2022, 20, 507-508.
  7. Clement Meseko; Adeyinka Adedeji; Ismaila Shittu; Emmanuel Obishakin; Maurice Nanven; Ladan Suleiman; Daniel Okomah; Visa Tyakaray; Damilola Kolade; Adesola Yinka-Ogunleye; Saleh Muhammad; Clint N. Morgan; Audrey Matheny; Yoshinori Nakazawa; Andrea McCollum; Jeffrey B. Doty; Orthopoxvirus Infections in Rodents, Nigeria, 2018–2019. Emerg. Infect. Dis.. 2023, 29, 433-434.
  8. Nengak D. Bsc Precious; Progress Bsc Agboola; Oladapo Bsc Oluwatimilehin; Olawale K. Bsc Olakunle; Peter Bsc Olaniyi; Azeez I. Bsc Adiatu; Agboola P. Bsc Olusogo; Danielle J. Bsc Obiwulu; Olowoyeye A. Bsc Adeola; Eze S. Bsc Ebubechukwu; Adebayo M. Bsc Oluwakayode; Olatokun S. Bsc Akano; Queen O. Bsc Kolawole; Re-emergence of monkeypox virus outbreak in Nigeria: epidemic preparedness and response (Review-Commentary). Ann. Med. Surg.. 2023, 85, 3990-3996.
  9. Mpox 2022 outbreak cases and data . Center for Disease Control. Retrieved 2024-10-17
  10. Update: Multistate Outbreak of Monkeypox --- Illinois, Indiana, Kansas, Missouri, Ohio, and Wisconsin, 2003 . Center for Disease Control. Retrieved 2024-10-17
  11. Aaron T. Fleischauer; James C. Kile; Molly Davidson; Marc Fischer; Kevin L. Karem; Robert Teclaw; Hans Messersmith; Pamela Pontones; Bradley A. Beard; Zachary H. Braden; Joanne Cono; James J. Sejvar; Ali S. Khan; Inger Damon; Matthew J. Kuehnert; Evaluation of Human-to-Human Transmission of Monkeypox from Infected Patients to Health Care Workers. Clin. Infect. Dis.. 2005, 40, 689-694.
  12. Christine Marie Kava; Dallas M. Rohraff; Bailey Wallace; Jennifer L. Mendoza-Alonzo; Dustin W. Currie; Anna E. Munsey; Nicole M. Roth; Jonathan Bryant-Genevier; Jordan L. Kennedy; Daniel L. Weller; Athalia Christie; Jennifer H. McQuiston; Peter Hicks; Penelope Strid; Emily Sims; Maria E. Negron; Kashif Iqbal; Sascha Ellington; Dawn K. Smith; Epidemiologic Features of the Monkeypox Outbreak and the Public Health Response — United States, May 17–October 6, 2022. Mmwr-Morbidity Mortal. Wkly. Rep.. 2022, 71, 1449-1456.
  13. Hugh Adler; Susan Gould; Paul Hine; Luke B Snell; Waison Wong; Catherine F Houlihan; Jane C Osborne; Tommy Rampling; Mike Bj Beadsworth; Christopher Ja Duncan; Jake Dunning; Tom E Fletcher; Ewan R Hunter; Michael Jacobs; Saye H Khoo; William Newsholme; David Porter; Robert J Porter; Libuše Ratcliffe; Matthias L Schmid; Malcolm G Semple; Anne J Tunbridge; Tom Wingfield; Nicholas M Price; Mike Abouyannis; Asma Al-Balushi; Stephen Aston; Robert Ball; Nicholas J Beeching; Thomas J Blanchard; Ffion Carlin; Geraint Davies; Angela Gillespie; Scott R Hicks; Marie-Claire Hoyle; Chinenye Ilozue; Luke Mair; Suzanne Marshall; Anne Neary; Emmanuel Nsutebu; Samantha Parker; Hannah Ryan; Lance Turtle; Chris Smith; Jon van Aartsen; Naomi F Walker; Stephen Woolley; Anu Chawla; Ian Hart; Anna Smielewska; Elizabeth Joekes; Cathryn Benson; Cheryl Brindley; Urmi Das; Chin K Eyton-Chong; Claire Gnanalingham; Clare Halfhide; Beatriz Larru; Sarah Mayell; Joanna McBride; Claire Oliver; Princy Paul; Andrew Riordan; Lekha Sridhar; Megan Storey; Audrey Abdul; Jennifer Abrahamsen; Breda Athan; Sanjay Bhagani; Colin S Brown; Oliver Carpenter; Ian Cropley; Kerrie Frost; Susan Hopkins; Jessica Joyce; Lucy Lamb; Adrian Lyons; Tabitha Mahungu; Stephen Mepham; Edina Mukwaira; Alison Rodger; Caroline Taylor; Simon Warren; Alan Williams; Debbie Levitt; Denise Allen; Jill Dixon; Adam Evans; Pauline McNicholas; Brendan Payne; D Ashley Price; Uli Schwab; Allison Sykes; Yusri Taha; Margaret Ward; Marieke Emonts; Stephen Owens; Alina Botgros; Sam T Douthwaite; Anna Goodman; Akish Luintel; Eithne MacMahon; Gaia Nebbia; Geraldine O'Hara; Joseph Parsons; Ashwin Sen; Daniel Stevenson; Tadgh Sullivan; Usman Taj; Claire van Nipsen Tot Pannerden; Helen Winslow; Ewa Zatyka; Ekene Alozie-Otuka; Csaba Beviz; Yusupha Ceesay; Latchmin Gargee; Morloh Kabia; Hannah Mitchell; Shona Perkins; Mingaile Sasson; Kamal Sehmbey; Federico Tabios; Neil Wigglesworth; Emma J Aarons; Tim Brooks; Matthew Dryden; Jenna Furneaux; Barry Gibney; Jennifer Small; Elizabeth Truelove; Clare E Warrell; Richard Firth; Gemma Hobson; Christopher Johnson; Alison Dewynter; Sebastian Nixon; Oliver Spence; Joachim J Bugert; Dennis E Hruby; Clinical features and management of human monkeypox: a retrospective observational study in the UK. Lancet Infect. Dis.. 2022, 22, 1153-1162.
  14. Aisling Vaughan; Emma Aarons; John Astbury; Tim Brooks; Meera Chand; Peter Flegg; Angela Hardman; Nick Harper; Richard Jarvis; Sharon Mawdsley; Mark McGivern; Dilys Morgan; Gwyn Morris; Grainne Nixon; Catherine O’cOnnor; Ruth Palmer; Nick Phin; D. Ashley Price; Katherine Russell; Bengu Said; Matthias L. Schmid; Roberto Vivancos; Amanda Walsh; William Welfare; Jennifer Wilburn; Jake Dunning; Human-to-Human Transmission of Monkeypox Virus, United Kingdom, October 2018. Emerg. Infect. Dis.. 2020, 26, 782-785.
  15. WHO Director-General’s statement at the press conference following IHR Emergency Committee regarding the multi-country outbreak of monkeypox . World Health Organization. Retrieved 2024-10-17
  16. WHO Director-General declares mpox outbreak a public health emergency of international concern . World Health Organization. Retrieved 2024-10-17
  17. Brian Greenwood; The contribution of vaccination to global health: past, present and future. Philos. Trans. R. Soc. B: Biol. Sci.. 2014, 369, 20130433.
  18. Sakshi Mbbs Watarkar; Prashant Upadhyay; Shankhaneel Mbbs Ghosh; Aditya A. Mbbs Godbole; Sai K. Mbbs Kishori; Aroop Mohanty; Bijaya K. Padhi; Ranjit Mbbs Sah; Vaccines for monkeypox disease and challenges in its production and distribution: a lesson from COVID-19 pandemic. Int. J. Surg.. 2023, 109, 536-538.
  19. Rahim Hirani; Kaleb Noruzi; Aroubah Iqbal; Anum S. Hussaini; Rafay A. Khan; Aleksandr Harutyunyan; Mill Etienne; Raj K. Tiwari; A Review of the Past, Present, and Future of the Monkeypox Virus: Challenges, Opportunities, and Lessons from COVID-19 for Global Health Security. Microorg.. 2023, 11, 2713.
  20. Jon Smith; Marc Lipsitch; Jeffrey W Almond; Vaccine production, distribution, access, and uptake. Lancet. 2011, 378, 428-438.
  21. Anne W. Rimoin; Prime M. Mulembakani; Sara C. Johnston; James O. Lloyd Smith; Neville K. Kisalu; Timothee L. Kinkela; Seth Blumberg; Henri A. Thomassen; Brian L. Pike; Joseph N. Fair; Nathan D. Wolfe; Robert L. Shongo; Barney S. Graham; Pierre Formenty; Emile Okitolonda; Lisa E. Hensley; Hermann Meyer; Linda L. Wright; Jean-Jacques Muyembe; Major increase in human monkeypox incidence 30 years after smallpox vaccination campaigns cease in the Democratic Republic of Congo. Proc. Natl. Acad. Sci.. 2010, 107, 16262-16267.
  22. Phi-Yen Nguyen; Whenayon Simeon Ajisegiri; Valentina Costantino; Abrar A. Chughtai; C. Raina MacIntyre; Reemergence of Human Monkeypox and Declining Population Immunity in the Context of Urbanization, Nigeria, 2017–2020. Emerg. Infect. Dis.. 2021, 27, 1007-1014.
  23. Ying-Hua Luo; Tong Zhang; Jing-Long Cao; Wen-Shuang Hou; An-Qi Wang; Cheng-Hao Jin; Monkeypox: An outbreak of a rare viral disease. J. Microbiol. Immunol. Infect.. 2023, 57, 1-10.
  24. Mary G. Reynolds; Inger K. Damon; Outbreaks of human monkeypox after cessation of smallpox vaccination. Trends Microbiol.. 2012, 20, 80-87.
  25. M. B. Townsend; M. S. Keckler; N. Patel; D. H. Davies; P. Felgner; I. K. Damon; K. L. Karem; Humoral Immunity to Smallpox Vaccines and Monkeypox Virus Challenge: Proteomic Assessment and Clinical Correlations. J. Virol.. 2013, 87, 900-911.
  26. Nathan P. Manes; Ryan D. Estep; Heather M. Mottaz; Ronald J. Moore; Therese R. W. Clauss; Matthew E. Monroe; Xiuxia Du; Joshua N. Adkins; Scott W. Wong; Richard D. Smith; Comparative Proteomics of Human Monkeypox and Vaccinia Intracellular Mature and Extracellular Enveloped Virions. J. Proteome Res.. 2008, 7, 960-968.
  27. Magdalena Molero-Abraham; John-Paul Glutting; Darren R. Flower; Esther M. Lafuente; Pedro A. Reche; EPIPOX: Immunoinformatic Characterization of the Shared T-Cell Epitome between Variola Virus and Related Pathogenic Orthopoxviruses. J. Immunol. Res.. 2015, 2015, 1-11.
  28. Mohammed Rafii-El-Idrissi Benhnia; Megan M. McCausland; Hua-Poo Su; Kavita Singh; Julia Hoffmann; D. Huw Davies; Philip L. Felgner; Steven Head; Alessandro Sette; David N. Garboczi; Shane Crotty; Redundancy and Plasticity of Neutralizing Antibody Responses Are Cornerstone Attributes of the Human Immune Response to the Smallpox Vaccine. J. Virol.. 2008, 82, 3751-3768.
  29. D. Huw Davies; Douglas M. Molina; Jens Wrammert; Joe Miller; Siddiqua Hirst; Yunxiang Mu; Jozelyn Pablo; Berkay Unal; Rie Nakajima‐Sasaki; Xiaowu Liang; Shane Crotty; Kevin L. Karem; Inger K. Damon; Rafi Ahmed; Luis Villarreal; Philip L. Felgner; Proteome‐wide analysis of the serological response to vaccinia and smallpox. Proteom.. 2007, 7, 1678-1686.
  30. Richard B. Kennedy; Inna G. Ovsyannikova; Iana H. Haralambieva; Diane E. Grill; Gregory A. Poland; Proteomic assessment of humoral immune responses in smallpox vaccine recipients. Vaccine. 2021, 40, 789-797.
  31. Lichen Jing; D. Huw Davies; Tiana M. Chong; Sookhee Chun; Christopher L. McClurkan; Jay Huang; Brian T. Story; Douglas M. Molina; Siddiqua Hirst; Philip L. Felgner; David M. Koelle; An Extremely Diverse CD4 Response to Vaccinia Virus in Humans Is Revealed by Proteome-Wide T-Cell Profiling. J. Virol.. 2008, 82, 7120-7134.
  32. Masanori Terajima; Laura Orphin; Anita M. Leporati; Pamela Pazoles; John Cruz; Alan L. Rothman; Francis A. Ennis; Vaccinia virus-specific CD8+ T-cell responses target a group of epitopes without a strong immunodominance hierarchy in humans. Hum. Immunol.. 2008, 69, 815-825.
  33. Lichen Jing; Tiana M. Chong; Christopher L. McClurkan; Jay Huang; Brian T. Story; David M. Koelle; Diversity in the Acute CD8 T Cell Response to Vaccinia Virus in Humans. J. Immunol.. 2005, 175, 7550-7559.
  34. Gregory A Poland; Richard B Kennedy; Pritish K Tosh; Prevention of monkeypox with vaccines: a rapid review. Lancet Infect. Dis.. 2022, 22, e349-e358.
  35. Richard B Kennedy; Inna G Ovsyannikova; Robert M Jacobson; Gregory A Poland; The immunology of smallpox vaccines. Curr. Opin. Immunol.. 2009, 21, 314-320.
  36. Interim Clinical Considerations for Use of JYNNEOS Vaccine for Mpox Prevention in the United States . Center for Disease Control. Retrieved 2024-10-17
  37. Marion F. Gruber; Current status of monkeypox vaccines. npj Vaccines. 2022, 7, 1-3.
  38. J Parrino; B Graham; Smallpox vaccines: Past, present, and future. J. Allergy Clin. Immunol.. 2006, 118, 1320-1326.
  39. Damian Jandrasits; Roland Züst; Denise Siegrist; Olivier B. Engler; Benjamin Weber; Kristina M. Schmidt; Hulda R. Jonsdottir; Third-generation smallpox vaccines induce low-level cross-protecting neutralizing antibodies against Monkeypox virus in laboratory workers. Heliyon. 2024, 10, e31490.
  40. Interim Clinical Considerations for Use of Vaccine for Mpox Prevention in the United States . Center for Disease Control. Retrieved 2024-10-17
  41. Vaccines Licensed for Use in the United States | FDA. FDA. Retrieved 2024-10-17
  42. Shelia M. Malone; Amal K. Mitra; Nwanne A. Onumah; Alexis Brown; Lena M. Jones; Da’chirion Tresvant; Cagney S. Brown; Austine U. Onyia; Faith O. Iseguede; Safety and Efficacy of Post-Eradication Smallpox Vaccine as an Mpox Vaccine: A Systematic Review with Meta-Analysis. Int. J. Environ. Res. Public Heal.. 2023, 20, 2963.
  43. Aniruddha Hazra; Jason Zucker; Elizabeth Bell; John Flores; Leanna Gordon; Oriol Mitjà; Clara Suñer; Adrien Lemaignen; Simon Jamard; Silvia Nozza; Achyuta V Nori; Edgar Pérez-Barragán; Juan Carlos Rodríguez-Aldama; Jose Louis Blanco; Constance Delaugerre; Dan Turner; Irene Fuertes; Viviana Leiro; Sharon L Walmsley; Chloe M Orkin; Catherine Creticos; Patrick Gibbons; Zoha Maakaroun-Vermesse; Cathie Faussat; Lynda Handala; Jeremy Zeggagh; Andrea Alemany; Cristina Galvan; Antonella Castagna; Angelo Roberto Raccagni; Raul Adrián Cruz-Flores; Patricia Fernandez Pardal; Lucila Marchetta; Mpox in people with past infection or a complete vaccination course: a global case series. Lancet Infect. Dis.. 2023, 24, 57-64.
  44. Sonja A. Rasmussen; Amelia K. Watson; Erin D. Kennedy; Karen R. Broder; Denise J. Jamieson; Vaccines and pregnancy: Past, present, and future. Semin. Fetal Neonatal Med.. 2014, 19, 161-169.
  45. Richard B. Kennedy; Inna Ovsyannikova; Gregory A. Poland; Smallpox vaccines for biodefense. Vaccine. 2009, 27, D73-D79.
  46. Barrett ADT, Stanberry LR. Vaccines for Biodefense and Emerging and Neglected Diseases ; Barrett ADT, Stanberry LR, Eds.; Elsevier Inc: Amsterdam, 2008; pp. 527–535.
  47. Mpox (monkeypox) vaccines. Australian Government Department of Health and Aged Care . Retrieved 2024-10-17
  48. Phillip R. Pittman; Matthew Hahn; HeeChoon S. Lee; Craig Koca; Nathaly Samy; Darja Schmidt; Joachim Hornung; Heinz Weidenthaler; Christopher R. Heery; Thomas P.H. Meyer; Günter Silbernagl; Jane Maclennan; Paul Chaplin; Phase 3 Efficacy Trial of Modified Vaccinia Ankara as a Vaccine against Smallpox. New Engl. J. Med.. 2019, 381, 1897-1908.
  49. Health Canada Extends Approval of IMVAMUNE to Immunization. GlobeNewsWire. Retrieved 2024-10-17
  50. Global monkeypox vaccine race sparks fears that poorer nations will lose out . The Guardian . Retrieved 2024-10-17
  51. Isaac Olushola Ogunkola; Oyinloye Emmanuel Abiodun; Babatunde Ismail Bale; Emmanuel Ebuka Elebesunu; Somtochukwu Blessing Ujam; Innocent Chimaobi Umeh; Mfoniso Tom-James; Shuaibu Saidu Musa; Emery Manirambona; Salvador B. Evardone; Don Eliseo Lucero-Prisno; Monkeypox vaccination in the global south: Fighting a war without a weapon. Clin. Epidemiology Glob. Heal.. 2023, 22, 101313-101313.
  52. Race for monkeypox vaccines exposes global health inequality. The Japan Times. Retrieved 2024-10-17
  53. Multi-country monkeypox outbreak declared a global Public Health Emergency of International Concern . Africa CDC. Retrieved 2024-10-17
  54. Support for Africa’s Vaccine Production is Good for the World . IMF Blog. Retrieved 2024-10-17
  55. Is There Any COVID-19 Vaccine Production in Africa?. Is There Any COVID-19 Vaccine Production in Africa?. Retrieved 2024-10-17
  56. G. Owen Schaefer; Ezekiel J. Emanuel; Caesar A. Atuire; R.J. Leland; Govind Persad; Henry S. Richardson; Carla Saenz; Equitable global allocation of monkeypox vaccines. Vaccine. 2023, 41, 7084-7088.
  57. David P. Fidler; Negotiating Equitable Access to Influenza Vaccines: Global Health Diplomacy and the Controversies Surrounding Avian Influenza H5N1 and Pandemic Influenza H1N1. PLOS Med.. 2010, 7, e1000247.
  58. Marcos Roberto Tovani-Palone; Neel Doshi; Paolo Pedersini; Inequity in the global distribution of monkeypox vaccines. World J. Clin. Cases. 2023, 11, 4498-4503.
  59. Tania Cernuschi; Shawn Gilchrist; Adnan Hajizada; Melissa Malhame; Stephanie Mariat; Greg Widmyer; Price transparency is a step towards sustainable access in middle income countries. BMJ. 2020, 368, l5375.
  60. Priyobrat Rajkhowa; Viola Savy Dsouza; Rashmi Kharel; K. Cauvery; B. Rashmi Mallya; D. S. Raksha; V. Mrinalini; Preejana Sharma; Sanjay Pattanshetty; Prakash Narayanan; Chandrakant Lahariya; Helmut Brand; Factors Influencing Monkeypox Vaccination: A Cue to Policy Implementation. J. Epidemiology Glob. Heal.. 2023, 13, 226-238.
  61. Om Prakash Choudhary; Priyanka; Mathumalar Loganathan Fahrni; AbdulRahman A. Saied; Hitesh Chopra; Ring vaccination for monkeypox containment: Strategic implementation and challenges. Int. J. Surg.. 2022, 105, 106873-106873.
  62. Sanjana Mukherjee; Kanika Kalra; Alexandra L. Phelan; Expanding global vaccine manufacturing capacity: Strategic prioritization in small countries. PLOS Glob. Public Heal.. 2023, 3, e0002098.
  63. 2022 Monkeypox outbreak global map : cases. Center for Disease Control. Retrieved 2024-10-17
  64. Ezekiel J. Emanuel; Govind Persad; Adam Kern; Allen Buchanan; Cécile Fabre; Daniel Halliday; Joseph Heath; Lisa Herzog; R. J. Leland; Ephrem T. Lemango; Florencia Luna; Matthew S. McCoy; Ole F. Norheim; Trygve Ottersen; G. Owen Schaefer; Kok-Chor Tan; Christopher Heath Wellman; Jonathan Wolff; Henry S. Richardson; An ethical framework for global vaccine allocation. Sci.. 2020, 369, 1309-1312.
  65. COVID-19 vaccinations shift to regular immunization as COVAX draws to a close. World Health Organization. Retrieved 2024-10-17
  66. Lukman Nul Hakim Md Khairi; Mathumalar Loganathan Fahrni; Antonio Ivan Lazzarino; The Race for Global Equitable Access to COVID-19 Vaccines. Vaccines. 2022, 10, 1306.
More
© Text is available under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/)
ScholarVision Creations
Feedback