Malaria vaccine
A malaria vaccine is a vaccine that is used to prevent malaria. The only approved vaccine as of 2015 is RTS,S, known by the trade name Mosquirix. It requires four injections, and has a relatively low efficacy. Due to this low efficacy, the World Health Organization (WHO) does not recommend the routine use of the RTS,S vaccine in babies between 6 and 12 weeks of age.[1]
Screened cup of malaria-infected mosquitoes which will infect a volunteer in a clinical trial | |
Vaccine description | |
---|---|
Target disease | Malaria |
Type | Protein subunit |
Clinical data | |
Trade names | Mosquirix |
Routes of administration | Intramuscular |
Identifiers | |
ChemSpider |
|
A WHO-led implementation program is piloting the vaccine in three high-malaria countries in Africa in 2019. The first phase of the project, covered by grants from Unitaid, Gavi and the Global Fund, is planned to establish the feasibility, impact and safety of RTS,S, when used as part of a routine immunization program.[2][3] Research continues into recombinant protein, attenuated whole organism and viral vectored vaccines.[4]
Approved vaccines
RTS,S
RTS,S (developed by PATH Malaria Vaccine Initiative (MVI) and GlaxoSmithKline (GSK) with support from the Bill and Melinda Gates Foundation) is the most recently developed recombinant vaccine. It consists of the P. falciparum circumsporozoite protein (CSP) from the pre-erythrocytic stage. The CSP antigen causes the production of antibodies capable of preventing the invasion of hepatocytes and additionally elicits a cellular response enabling the destruction of infected hepatocytes. The CSP vaccine presented problems in trials due to its poor immunogenicity. RTS,S attempted to avoid these by fusing the protein with a surface antigen from hepatitis B, hence creating a more potent and immunogenic vaccine. When tested in trials an emulsion of oil in water and the added adjuvants of monophosphoryl A and QS21 (SBAS2), the vaccine gave protective immunity to 7 out of 8 volunteers when challenged with P. falciparum.[5]
RTS,S/AS01 (commercial name Mosquirix),[6] was engineered using genes from the outer protein of P. falciparum malaria parasite and a portion of a hepatitis B virus plus a chemical adjuvant to boost the immune response. Infection is prevented by inducing high antibody titers that block the parasite from infecting the liver.[7] In November 2012 a Phase III trial of RTS,S found that it provided modest protection against both clinical and severe malaria in young infants.[8]
As of October 2013, preliminary results of a phase III clinical trial indicated that RTS,S/AS01 reduced the number of cases among young children by almost 50 percent and among infants by around 25 percent. The study ended in 2014. The effects of a booster dose were positive, even though overall efficacy seem to wane with time. After four years reductions were 36 percent for children who received three shots and a booster dose. Missing the booster dose reduced the efficacy against severe malaria to a negligible effect. The vaccine was shown to be less effective for infants. Three doses of vaccine plus a booster reduced the risk of clinical episodes by 26 percent over three years, but offered no significant protection against severe malaria.[9]
In a bid to accommodate a larger group and guarantee a sustained availability for the general public, GSK applied for a marketing license with the European Medicines Agency (EMA) in July 2014.[10] GSK treated the project as a non-profit initiative, with most funding coming from the Gates Foundation, a major contributor to malaria eradication.[11]
On 24 July 2015, Mosquirix received a positive opinion from the EMA on the proposal of the vaccine to be used to vaccinate children aged 6 weeks to 17 months outside the European Union.[12][13][14]
Pilot project for vaccination has been launched on 23 April 2019 in Malawi, on 30 April 2019 in Ghana, and on 13 September 2019 in Kenya.[15][16]
Considerations
The task of developing a preventive vaccine for malaria is a complex process. There are a number of considerations to be made concerning what strategy a potential vaccine should adopt.
Parasite diversity
P. falciparum has demonstrated the capability, through the development of multiple drug-resistant parasites, for evolutionary change. The Plasmodium species has a very high rate of replication, much higher than that actually needed to ensure transmission in the parasite's life cycle. This enables pharmaceutical treatments that are effective at reducing the reproduction rate, but not halting it, to exert a high selection pressure, thus favoring the development of resistance. The process of evolutionary change is one of the key considerations necessary when considering potential vaccine candidates. The development of resistance could cause a significant reduction in efficacy of any potential vaccine thus rendering useless a carefully developed and effective treatment.[17]
Choosing to address the symptom or the source
The parasite induces two main response types from the human immune system. These are anti-parasitic immunity and anti-toxic immunity.
- "Anti-parasitic immunity" addresses the source; it consists of an antibody response (humoral immunity) and a cell-mediated immune response. Ideally a vaccine would enable the development of anti-plasmodial antibodies in addition to generating an elevated cell-mediated response. Potential antigens against which a vaccine could be targeted will be discussed in greater depth later. Antibodies are part of the specific immune response. They exert their effect by activating the complement cascade, stimulating phagocytic cells into endocytosis through adhesion to an external surface of the antigenic substances, thus 'marking' it as offensive. Humoral or cell-mediated immunity consists of many interlinking mechanisms that essentially aim to prevent infection entering the body (through external barriers or hostile internal environments) and then kill any micro-organisms or foreign particles that succeed in penetration. The cell-mediated component consists of many white blood cells (such as monocytes, neutrophils, macrophages, lymphocytes, basophils, mast cells, natural killer cells, and eosinophils) that target foreign bodies by a variety of different mechanisms. In the case of malaria both systems would be targeted to attempt to increase the potential response generated, thus ensuring the maximum chance of preventing disease.
- "Anti-toxic immunity" addresses the symptoms; it refers to the suppression of the immune response associated with the production of factors that either induce symptoms or reduce the effect that any toxic by-products (of micro-organism presence) have on the development of disease. For example, it has been shown that Tumor necrosis factor-alpha has a central role in generating the symptoms experienced in severe P. falciparum malaria. Thus a therapeutic vaccine could target the production of TNF-a, preventing respiratory distress and cerebral symptoms. This approach has serious limitations as it would not reduce the parasitic load; rather it only reduces the associated pathology. As a result, there are substantial difficulties in evaluating efficacy in human trials.
Taking this information into consideration an ideal vaccine candidate would attempt to generate a more substantial cell-mediated and antibody response on parasite presentation. This would have the benefit of increasing the rate of parasite clearance, thus reducing the experienced symptoms and providing a level of consistent future immunity against the parasite.
Potential targets
Parasite stage | Target |
---|---|
Sporozoite | Hepatocyte invasion; direct anti-sporozite |
Hepatozoite | Direct anti-hepatozoite. |
Asexual erythrocytic | Anti-host erythrocyte, antibodies blocking invasion; anti receptor ligand, anti-soluble toxin |
Gametocytes | Anti-gametocyte. Anti-host erythrocyte, antibodies blocking fertilisation, antibodies blocking egress from the mosquito midgut. |
By their very nature, protozoa are more complex organisms than bacteria and viruses, with more complicated structures and life cycles. This presents problems in vaccine development but also increases the number of potential targets for a vaccine. These have been summarised into the life cycle stage and the antibodies that could potentially elicit an immune response.
The epidemiology of malaria varies enormously across the globe, and has led to the belief that it may be necessary to adopt very different vaccine development strategies to target the different populations. A Type 1 vaccine is suggested for those exposed mostly to P. falciparum malaria in sub-Saharan Africa, with the primary objective to reduce the number of severe malaria cases and deaths in infants and children exposed to high transmission rates. The Type 2 vaccine could be thought of as a 'travellers' vaccine', aiming to prevent all cases of clinical symptoms in individuals with no previous exposure. This is another major public health problem, with malaria presenting as one of the most substantial threats to travellers' health. Problems with the current available pharmaceutical therapies include costs, availability, adverse effects and contraindications, inconvenience and compliance, many of which would be reduced or eliminated entirely if an effective (greater than 85–90%) vaccine was developed.
The life cycle of the malaria parasite is particularly complex, presenting initial developmental problems. Despite the huge number of vaccines available at the current time, there are none that target parasitic infections. The distinct developmental stages involved in the life cycle present numerous opportunities for targeting antigens, thus potentially eliciting an immune response. Theoretically, each developmental stage could have a vaccine developed specifically to target the parasite. Moreover, any vaccine produced would ideally have the ability to be of therapeutic value as well as preventing further transmission and is likely to consist of a combination of antigens from different phases of the parasite's development. More than 30 of these antigens are currently being researched by teams all over the world in the hope of identifying a combination that can elicit immunity in the inoculated individual. Some of the approaches involve surface expression of the antigen, inhibitory effects of specific antibodies on the life cycle and the protective effects through immunization or passive transfer of antibodies between an immune and a non-immune host. The majority of research into malarial vaccines has focused on the Plasmodium falciparum strain due to the high mortality caused by the parasite and the ease of a carrying out in vitro/in vivo studies. The earliest vaccines attempted to use the parasitic circumsporozoite (CS) protein. This is the most dominant surface antigen of the initial pre-erythrocytic phase. However, problems were encountered due to low efficacy, reactogenicity and low immunogenicity.
- The initial stage in the life cycle, following inoculation, is a relatively short "pre-erythrocytic" or "hepatic" phase. A vaccine at this stage must have the ability to protect against sporozoites invading and possibly inhibiting the development of parasites in the hepatocytes (through inducing cytotoxic T-lymphocytes that can destroy the infected liver cells). However, if any sporozoites evaded the immune system they would then have the potential to be symptomatic and cause the clinical disease.
- The second phase of the life cycle is the "erythrocytic" or blood phase. A vaccine here could prevent merozoite multiplication or the invasion of red blood cells. This approach is complicated by the lack of MHC molecule expression on the surface of erythrocytes. Instead, malarial antigens are expressed, and it is this towards which the antibodies could potentially be directed. Another approach would be to attempt to block the process of erythrocyte adherence to blood vessel walls. It is thought that this process is accountable for much of the clinical syndrome associated with malarial infection; therefore a vaccine given during this stage would be therapeutic and hence administered during clinical episodes to prevent further deterioration.
- The last phase of the life cycle that has the potential to be targeted by a vaccine is the "sexual stage". This would not give any protective benefits to the individual inoculated but would prevent further transmission of the parasite by preventing the gametocytes from producing multiple sporozoites in the gut wall of the mosquito. It therefore would be used as part of a policy directed at eliminating the parasite from areas of low prevalence or to prevent the development and spread of vaccine-resistant parasites. This type of transmission-blocking vaccine is potentially very important. The evolution of resistance in the malaria parasite occurs very quickly, potentially making any vaccine redundant within a few generations. This approach to the prevention of spread is therefore essential.
- Another approach is to target the protein kinases, which are present during the entire lifecycle of the malaria parasite. Research is underway on this, yet production of an actual vaccine targeting these protein kinases may still take a long time.[18]
- Report of a new candidate of vaccine capable to neutralize all tested strains of Plasmodium falciparum, the most deadly form of the parasite causing malaria, was published in Nature Communications by a team of scientists from the University of Oxford in 2011.[19] The viral vectored vaccine, targeting a full-length P. falciparum reticulocyte-binding protein homologue 5 (PfRH5) was found to induce an antibody response in an animal model. The results of this new vaccine confirmed the utility of a key discovery reported from scientists at the Wellcome Trust Sanger Institute, published in Nature.[20] The earlier publication reported P. falciparum relies on a red blood cell surface receptor, known as 'basigin', to invade the cells by binding a protein PfRH5 to the receptor.[20] Unlike other antigens of the malaria parasite which are often genetically diverse, the PfRH5 antigen appears to have little genetic diversity. It was found to induce very low antibody response in people naturally exposed to the parasite.[19] The high susceptibility of PfRH5 to the cross-strain neutralizing vaccine-induced antibody demonstrated a significant promise for preventing malaria in the long and often difficult road of vaccine development. According to Professor Adrian Hill, a Wellcome Trust Senior Investigator at the University of Oxford, the next step would be the safety tests of this vaccine. At the time (2011) it was projected that if these proved successful, the clinical trials in patients could begin within two to three years.[21]
- PfEMP1, one of the proteins known as variant surface antigens (VSAs) produced by Plasmodium falciparum, was found to be a key target of the immune system's response against the parasite. Studies of blood samples from 296 mostly Kenyan children by researchers of Burnet Institute and their cooperators showed that antibodies against PfEMP1 provide protective immunity, while antibodies developed against other surface antigens do not. Their results demonstrated that PfEMP1 could be a target to develop an effective vaccine which will reduce risk of developing malaria.[22][23]
- Plasmodium vivax is the common malaria species found in India, Southeast Asia and South America. It is able to stay dormant in the liver and reemerge years later to elicit new infections. Two key proteins involved in the invasion of the red blood cells (RBC) by P. vivax are potential targets for drug or vaccine development. When the Duffy binding protein (DBP) of P. vivax binds the Duffy antigen (DARC) on the surface of RBC, process for the parasite to enter the RBC is initiated. Structures of the core region of DARC and the receptor binding pocket of DBP have been mapped by scientists at the Washington University in St. Louis. The researchers found that the binding is a two-step process which involves two copies of the parasite protein acting together like a pair of tongs which 'clamp two copies of DARC. Antibodies that interfere with the binding, by either targeting the key region of the DARC or the DBP will prevent the infection.[24][25]
- Antibodies against the Schizont Egress Antigen-1 (PfSEA-1) were found to disable the parasite ability to rupture from the infected red blood cells (RBCs) thus prevent it from continuing with its life cycle. Researchers from Rhode Island Hospital identified Plasmodium falciparum PfSEA-1, a 244 kd malaria antigen expressed in the schizont-infected RBCs. Mice vaccinated with the recombinant PfSEA-1 produced antibodies which interrupted the schizont rupture from the RBCs and decreased the parasite replication. The vaccine protected the mice from lethal challenge of the parasite. Tanzanian and Kenyan children who have antibodies to PfSEA-1 were found to have fewer parasites in their blood stream and milder case of malaria. By blocking the schizont outlet, the PfSEA-1 vaccine may work synergistically with vaccines targeting the other stages of the malaria life cycle such as hepatocyte and RBC invasion.[26][27]
Mix of antigenic components
Increasing the potential immunity generated against Plasmodia can be achieved by attempting to target multiple phases in the life cycle. This is additionally beneficial in reducing the possibility of resistant parasites developing. The use of multiple-parasite antigens can therefore have a synergistic or additive effect.
One of the most successful vaccine candidates currently in clinical trials consists of recombinant antigenic proteins to the circumsporozoite protein.[28] (This is discussed in more detail below.)
Delivery system
The selection of an appropriate system is fundamental in all vaccine development, but especially so in the case of malaria. A vaccine targeting several antigens may require delivery to different areas and by different means in order to elicit an effective response. Some adjuvants can direct the vaccine to the specifically targeted cell type—e.g. the use of Hepatitis B virus in the RTS,S vaccine to target infected hepatocytes—but in other cases, particularly when using combined antigenic vaccines, this approach is very complex. Some methods that have been attempted include the use of two vaccines, one directed at generating a blood response and the other a liver-stage response. These two vaccines could then be injected into two different sites, thus enabling the use of a more specific and potentially efficacious delivery system.
To increase, accelerate or modify the development of an immune response to a vaccine candidate it is often necessary to combine the antigenic substance to be delivered with an adjuvant or specialised delivery system. These terms are often used interchangeably in relation to vaccine development; however in most cases a distinction can be made. An adjuvant is typically thought of as a substance used in combination with the antigen to produce a more substantial and robust immune response than that elicited by the antigen alone. This is achieved through three mechanisms: by affecting the antigen delivery and presentation, by inducing the production of immunomodulatory cytokines, and by affecting the antigen presenting cells (APC). Adjuvants can consist of many different materials, from cell microparticles to other particulated delivery systems (e.g. liposomes).
Adjuvants are crucial in affecting the specificity and isotype of the necessary antibodies. They are thought to be able to potentiate the link between the innate and adaptive immune responses. Due to the diverse nature of substances that can potentially have this effect on the immune system, it is difficult to classify adjuvants into specific groups. In most circumstances they consist of easily identifiable components of micro-organisms that are recognised by the innate immune system cells. The role of delivery systems is primarily to direct the chosen adjuvant and antigen into target cells to attempt to increase the efficacy of the vaccine further, therefore acting synergistically with the adjuvant.
There is increasing concern that the use of very potent adjuvants could precipitate autoimmune responses, making it imperative that the vaccine is focused on the target cells only. Specific delivery systems can reduce this risk by limiting the potential toxicity and systemic distribution of newly developed adjuvants.
Studies into the efficacy of malaria vaccines developed to date have illustrated that the presence of an adjuvant is key in determining any protection gained against malaria. A large number of natural and synthetic adjuvants have been identified throughout the history of vaccine development. Options identified thus far for use combined with a malaria vaccine include mycobacterial cell walls, liposomes, monophosphoryl lipid A and squalene.
Agents under development
A completely effective vaccine is not yet available for malaria, although several vaccines are under development. SPf66 a synthetic peptide based vaccine developed by Manuel Elkin Patarroyo team in Colombia was tested extensively in endemic areas in the 1990s, but clinical trials showed it to be insufficiently effective, 28% efficacy in South America and minimal or no efficacy in Africa.[29] Other vaccine candidates, targeting the blood-stage of the parasite's life cycle, have also been insufficient on their own.[30] Several potential vaccines targeting the pre-erythrocytic stage are being developed, with RTS,S showing the most promising results so far.,[31][8]
- The CSP (Circum-Sporozoite Protein) was a vaccine developed that initially appeared promising enough to undergo trials. It is also based on the circumsporozoite protein, but additionally has the recombinant (Asn-Ala-Pro15Asn-Val-Asp-Pro)2-Leu-Arg(R32LR) protein covalently bound to a purified Pseudomonas aeruginosa toxin (A9). However at an early stage a complete lack of protective immunity was demonstrated in those inoculated. The study group used in Kenya had an 82% incidence of parasitaemia whilst the control group only had an 89% incidence. The vaccine intended to cause an increased T-lymphocyte response in those exposed, this was also not observed.
- The NYVAC-Pf7 multi-stage vaccine attempted to use different technology, incorporating seven P.falciparum antigenic genes. These came from a variety of stages during the life cycle. CSP and sporozoite surface protein 2 (called PfSSP2) were derived from the sporozoite phase. The liver stage antigen 1 (LSA1), three from the erythrocytic stage (merozoite surface protein 1, serine repeat antigen and AMA-1) and one sexual stage antigen (the 25-kDa Pfs25) were included. This was first investigated using Rhesus monkeys and produced encouraging results: 4 out of the 7 antigens produced specific antibody responses (CSP, PfSSP2, MSP1 and PFs25). Later trials in humans, despite demonstrating cellular immune responses in over 90% of the subjects, had very poor antibody responses. Despite this following administration of the vaccine some candidates had complete protection when challenged with P.falciparum. This result has warranted ongoing trials.
- In 1995 a field trial involving [NANP]19-5.1 proved to be very successful. Out of 194 children vaccinated none developed symptomatic malaria in the 12-week follow up period and only 8 failed to have higher levels of antibody present. The vaccine consists of the schizont export protein (5.1) and 19 repeats of the sporozoite surface protein [NANP]. Limitations of the technology exist as it contains only 20% peptide and has low levels of immunogenicity. It also does not contain any immunodominant T-cell epitopes.[32]
Nanoparticle enhancement of RTS,S
In 2015, researchers used a repetitive antigen display technology to engineer a nanoparticle that displayed malaria specific B cell and T cell epitopes. The particle exhibited icosahedral symmetry and carried on its surface up to 60 copies of the RTS,S protein. The researchers claimed that the density of the protein was much higher than the 14% of the GSK vaccine.[33][34]
PfSPZ vaccine
The PfSPZ vaccine is a candidate malaria vaccine developed by Sanaria using radiation-attenuated sporozoites to elicit an immune response. Clinical trials have been promising, with trials taking place in Africa, Europe, and the US protecting over 80% of volunteers. It has been subject to some criticism regarding the ultimate feasibility of large-scale production and delivery in Africa, since it must be stored in liquid nitrogen.
The PfSPZ vaccine candidate has been granted fast track designation by the U.S. Food and Drug Administration in September 2016.[35]
History
Individuals who are exposed to the parasite in endemic countries develop acquired immunity against disease and death. Such immunity does not however prevent malarial infection; immune individuals often harbour asymptomatic parasites in their blood. This does, however, imply that it is possible to create an immune response that protects against the harmful effects of the parasite.
Research shows that if immunoglobulin is taken from immune adults, purified and then given to individuals who have no protective immunity, some protection can be gained.[36]
Irradiated mosquitoes
In 1967, it was reported that a level of immunity to the Plasmodium berghei parasite could be given to mice by exposing them to sporozoites that had been irradiated by x-rays.[37] Subsequent human studies in the 1970s showed that humans could be immunized against Plasmodium vivax and Plasmodium falciparum by exposing them to the bites of significant numbers of irradiated mosquitos.[38]
From 1989 to 1999, eleven volunteers recruited from the United States Public Health Service, United States Army, and United States Navy were immunized against Plasmodium falciparum by the bites of 1001–2927 mosquitoes that had been irradiated with 15,000 rads of gamma rays from a Co-60 or Cs-137 source.[39] This level of radiation is sufficient to attenuate the malaria parasites so that, while they can still enter hepatic cells, they cannot develop into schizonts nor infect red blood cells.[39] Over a span of 42 weeks, 24 of 26 tests on the volunteers showed that they were protected from malaria.[40]
References
- "Malaria vaccine: WHO position paper – January 2016" (PDF). Weekly Epidemiological Record. 91 (4): 33–52. 4 November 2016. PMID 26829826. Lay summary (PDF).
- "Piloting the world's first malaria vaccine". Unitaid. Retrieved 17 April 2019.
- "Ghana, Kenya and Malawi to take part in WHO malaria vaccine pilot programme". Retrieved 27 April 2017.
- Stanisic, Danielle I.; Fink, James; Mayer, Johanna; Coghill, Sarah; Gore, Letitia; Liu, Xue Q.; El-Deeb, Ibrahim; Rodriguez, Ingrid B.; Powell, Jessica; Willemsen, Nicole M.; De, Sai Lata; Ho, Mei-Fong; Hoffman, Stephen L.; Gerrard, John; Good, Michael F. (8 October 2018). "Vaccination with chemically attenuated Plasmodium falciparum asexual blood-stage parasites induces parasite-specific cellular immune responses in malaria-naïve volunteers: a pilot study". BMC Medicine. 16 (1): 184. doi:10.1186/s12916-018-1173-9. PMC 6174572. PMID 30293531.
- "RTS,S malaria candidate vaccine reduces malaria by approximately one-third in African infants". malariavaccine.org. Malaria Vaccine Initiative Path. Archived from the original on 23 March 2013. Retrieved 19 March 2013.
- "Commercial name of RTS,S". Archived from the original on 5 April 2012. Retrieved 20 October 2011.
- Foquet, Lander; Hermsen, Cornelus; van Gemert, Geert-Jan; Van Braeckel, Eva; Weening, Karin; Sauerwein, Robert; Meuleman, Philip; Leroux-Roels, Geert (2014). "Vaccine-induced monoclonal antibodies targeting circumsporozoite protein prevent Plasmodium falciparum infection". Journal of Clinical Investigation. 124 (1): 140–4. doi:10.1172/JCI70349. PMC 3871238. PMID 24292709.
- RTS,S Clinical Trials Partnership; Agnandji, S. T.; Lell, B.; Fernandes, J. F.; Abossolo, B. P.; Methogo, B. G.; Kabwende, A. L.; Adegnika, A. A.; Mordmüller, B.; Issifou, S.; Kremsner; Sacarlal, J.; Aide, P.; Lanaspa, M.; Aponte, J. J.; Machevo, S.; Acacio, S.; Bulo, H.; Sigauque, B.; MacEte, E.; Alonso; Abdulla, S.; Salim, N.; Minja, R.; Mpina, M.; Ahmed, S.; Ali, A. M.; Mtoro, A. T.; Hamad, A. S.; et al. (December 2012). "A Phase 3 Trial of RTS,S/AS01 Malaria Vaccine in African Infants" (PDF). New England Journal of Medicine. 367 (24): 2284–2295. doi:10.1056/NEJMoa1208394. PMID 23136909.
- Borghino, Dario (27 April 2015). "Malaria vaccine candidate shown to prevent thousands of cases". www.gizmag.com. Retrieved 11 June 2016.
- "GSK announces EU regulatory submission of malaria vaccine candidate RTS,S" (Press release). GSK. 24 July 2014. Archived from the original on 4 December 2016. Retrieved 30 July 2015.
- Kelland, Kate (7 October 2013). "GSK aims to market world's first malaria vaccine". Reuters. Retrieved 9 December 2013.
- "First malaria vaccine receives positive scientific opinion from EMA" (Press release). European Medicines Agency (EMA). 24 July 2015. Retrieved 30 July 2015.
- "GSK's malaria candidate vaccine, Mosquirix (RTS,S), receives positive opinion from European regulators for the prevention of malaria in young children in sub-Saharan Africa" (Press release). GSK. 24 July 2015. Archived from the original on 28 July 2015. Retrieved 30 July 2015.
- "Mosquirix H-W-2300". European Medicines Agency (EMA). 17 September 2018. Archived from the original on 23 November 2019. Retrieved 22 November 2019.
- Alonso, Pedro (19 June 2019). "Letter to partners – June 2019" (Press release). Wuxi: World Health Organization. Retrieved 22 October 2019.
- "Malaria vaccine launched in Kenya: Kenya joins Ghana and Malawi to roll out landmark vaccine in pilot introduction" (Press release). Homa Bay: World Health Organization. 13 September 2019. Retrieved 22 October 2019.
- Kennedy, David A.; Read, Andrew F. (18 December 2018). "Why the evolution of vaccine resistance is less of a concern than the evolution of drug resistance". Proceedings of the National Academy of Sciences of the United States of America. 115 (51): 12878–12886. doi:10.1073/pnas.1717159115. ISSN 0027-8424. PMC 6304978. PMID 30559199.
- Zhang VM, Chavchich M, Waters NC (March 2012). "Targeting protein kinases in the malaria parasite: update of an antimalarial drug target". Curr Top Med Chem. 12 (5): 456–72. doi:10.2174/156802612799362922. PMID 22242850. Archived from the original on 30 May 2013. Retrieved 23 March 2020.
- Douglas, Alexander; et, al (2011). "The blood-stage malaria antigen PfRH5 is susceptible to vaccine-inducible cross-strain neutralizing antibody". Nature Communications. 2 (12): 601. Bibcode:2011NatCo...2E.601D. doi:10.1038/ncomms1615. PMC 3504505. PMID 22186897.
- Crosnier, Cecile; et, al (2011). "Basigin is a receptor essential for erythrocyte invasion by Plasmodium falciparum". Nature. 480 (7378): 534–537. Bibcode:2011Natur.480..534C. doi:10.1038/nature10606. PMC 3245779. PMID 22080952.
- Martino, Maureen (21 December 2011). "New candidate vaccine neutralizes all tested strains of malaria parasite". fiercebiotech.com. FierceBiotech. Retrieved 23 December 2011.
- Parish, Tracy (2 August 2012). "Lifting malaria's deadly veil: Mystery solved in quest for vaccine". Burnet Institute. Retrieved 14 August 2012.
- Chan, Jo-Anne; Howell, Katherine; Reiling, Linda; Ataide, Ricardo; Mackintosh, Claire; Fowkes, Freya; Petter, Michaela; Chesson, Joanne; Langer, Christine; Warimwe, George (2012). "Targets of antibodies against Plasmodium falciparum-infected erythrocytes in malaria immunity". Journal of Clinical Investigation. 122 (9): 3227–3238. doi:10.1172/JCI62182. PMC 3428085. PMID 22850879.
- Mullin, Emily (13 January 2014). "Scientists capture key protein structures that could aid malaria vaccine design". fiercebiotechresearch.com. Retrieved 16 January 2014.
- Batchelor, J.; Malpede, B.; Omattage, N.; DeKoster, G.; Henzler-Wildman, K.; Tolia, N. (2014). "Red Blood Cell Invasion by Plasmodium vivax: Structural Basis for DBP Engagement of DARC". PLOS Pathogens. 10 (1): e1003869. doi:10.1371/journal.ppat.1003869. PMC 3887093. PMID 24415938.
- Mullin, Emily (27 May 2014). "Antigen Discovery could advance malaria vaccine". fiercebiotechresearch.com. Retrieved 22 June 2014.
- Raj, D; Kurtis, J; et al. (2014). "Antibodies to PfSEA-1 block parasite egress from RBCs and protect against malaria infection". Science. 344 (6186): 871–877. Bibcode:2014Sci...344..871R. doi:10.1126/science.1254417. PMC 4184151. PMID 24855263.
- Plassmeyer ML, Reiter K, Shimp RL, et al. (July 2009). "Structure of the Plasmodium falciparum Circumsporozoite Protein, a Leading Malaria Vaccine Candidate". J. Biol. Chem. 284 (39): 26951–63. doi:10.1074/jbc.M109.013706. PMC 2785382. PMID 19633296.
- Graves P, Gelband H (2006). "Vaccines for preventing malaria (SPf66)". Cochrane Database Syst Rev (2): CD005966. doi:10.1002/14651858.CD005966. PMC 6532709. PMID 16625647.
- Graves P, Gelband H (2006). "Vaccines for preventing malaria (blood-stage)". Cochrane Database Syst Rev (4): CD006199. doi:10.1002/14651858.CD006199. PMC 6532641. PMID 17054281.
- Graves P, Gelband H (2006). "Vaccines for preventing malaria (pre-erythrocytic)". Cochrane Database Syst Rev (4): CD006198. doi:10.1002/14651858.CD006198. PMC 6532586. PMID 17054280.
- Ratanji, Kirsty D.; Derrick, Jeremy P.; Dearman, Rebecca J.; Kimber, Ian (April 2014). "Immunogenicity of therapeutic proteins: Influence of aggregation". Journal of Immunotoxicology. 11 (2): 99–109. doi:10.3109/1547691X.2013.821564. ISSN 1547-691X. PMC 4002659. PMID 23919460.
- "Researcher's nanoparticle key to new malaria vaccine". Research & Development. 4 September 2014. Retrieved 12 June 2016.
- Burkhard, Peter; Lanar, David E. (2 December 2015). "Malaria vaccine based on self-assembling protein nanoparticles". Expert Review of Vaccines. 14 (12): 1525–1527. doi:10.1586/14760584.2015.1096781. ISSN 1476-0584. PMC 5019124. PMID 26468608.
- "SANARIA PfSPZ VACCINE AGAINST MALARIA RECEIVES FDA FAST TRACK DESIGNATION" (PDF). Sanaria Inc. 22 September 2016. Archived from the original (PDF) on 23 October 2016. Retrieved 23 January 2017.
- "Immunoglobulin Therapy & Other Medical Therapies for Antibody Deficiencies". Immune Deficiency Foundation. Retrieved 30 September 2019.
- Nussenzweig, Ruth; J. VANDERBERG; H. MOST; C. ORTON (14 October 1967). "Protective Immunity produced by the Injection of X-irradiated Sporozoites of Plasmodium berghei". Nature. 216 (5111): 160–162. Bibcode:1967Natur.216..160N. doi:10.1038/216160a0. PMID 6057225. Retrieved 9 August 2013.
- Clyde, D. F. (1975). "Immunization of man against falciparum and vivax malaria by use of attenuated sporozoites". The American Journal of Tropical Medicine and Hygiene. 24 (3): 397–401. doi:10.4269/ajtmh.1975.24.397. PMID 808142.
- Hoffman, Stephen L. (2002). "Protection of Humans against Malaria by Immunization with Radiation-Attenuated Plasmodium falciparum Sporozoites". The Journal of Infectious Diseases. 185 (8): 1155–1164. doi:10.1086/339409. PMID 11930326. Retrieved 9 August 2013.
- Hoffman, S. L.; Goh, L. M.; Luke, T. C.; Schneider, I.; Le, T. P.; Doolan, D. L.; Sacci, J.; de la Vega, P.; Dowler, M.; Paul, C.; Gordon, D. M.; Stoute, J. A.; Church, L. W.; Sedegah, M.; Heppner, D. G.; Ballou, W. R.; Richie, T. L. (15 April 2002). "Protection of humans against malaria by immunization with radiation-attenuated Plasmodium falciparum sporozoites". The Journal of Infectious Diseases. 185 (8): 1155–64. doi:10.1086/339409. PMID 11930326.
Bibliography
- Good, Michael F.; Levine, Myron A.; James B. Kaper; Rappuoli, Rino; Liu, Margaret A (2004). New Generation Vaccines. New York, N.Y: Marcel Dekker. ISBN 978-0-8247-4071-9.
- Hoffman; et al. "Malaria: A Complex Disease that May Require a Complex Vaccine". ibid.
- Good, M.; Kemp, D. "Overview of Vaccine Strategies for Malaria". ibid.
- Saul, A. "Malaria Transmission-Blocking Vaccines". ibid.
- Heppner; et al. "Adjuvanted RTS,S and Other Protein- Based Pre-Erythrocytic Stage Malaria Vaccines". ibid.
- Good; et al. "Plasmodium falciparum Asexual Vaccine Candidates: Current Status". ibid.
- The Jordan Report
- "Case studies: Potential malaria vaccine" (Press release). GlaxoSmithKline. 21 August 2009. Archived from the original on 27 July 2009. Retrieved 27 November 2009.
- "World's largest malaria vaccine trial now underway in seven African countries" (Press release). GlaxoSmithKline. 3 November 2009. Archived from the original on 10 November 2009. Retrieved 27 November 2009.
- Abdulla S, Oberholzer R, Juma O, et al. (December 2008). "Safety and immunogenicity of RTS,S/AS02D malaria vaccine in infants" (PDF). The New England Journal of Medicine. 359 (24): 2533–44. doi:10.1056/NEJMoa0807773. PMID 19064623.
- Aponte JJ, Aide P, Renom M, et al. (November 2007). "Safety of the RTS,S/AS02D candidate malaria vaccine in infants living in a highly endemic area of Mozambique: a double blind randomised controlled phase I/IIb trial". The Lancet. 370 (9598): 1543–51. doi:10.1016/S0140-6736(07)61542-6. PMID 17949807.
- Bejon P, Lusingu J, Olotu A, et al. (December 2008). "Efficacy of RTS,S/AS01E Vaccine against Malaria in Children 5 to 17 Months of Age". The New England Journal of Medicine. 359 (24): 2521–32. doi:10.1056/NEJMoa0807381. PMC 2655100. PMID 19064627.
- Delves, Peter J.; Roitt, Ivan Maurice (2001). Roitt's essential immunology. Oxford: Blackwell Science. ISBN 978-0-632-05902-7.
- Gurunathan S, Klinman DM, Seder RA (2000). "DNA vaccines: immunology, application, and optimization". Annu. Rev. Immunol. 18: 927–74. doi:10.1146/annurev.immunol.18.1.927. PMID 10837079.
- Schwartz, L.; Brown, G. V.; Genton, B.; Moorthy, V. S. (2012). "A review of malaria vaccine clinical projects based on the WHO rainbow table". Malaria Journal. 11: 11. doi:10.1186/1475-2875-11-11. PMC 3286401. PMID 22230255.
- Waters A (February 2006). "Malaria: new vaccines for old?". Cell. 124 (4): 689–93. doi:10.1016/j.cell.2006.02.011. PMID 16497579.
External links
- Malaria Vaccine Initiative
- Malaria vaccines UK
- Gates Foundation Global Health: Malaria
- Brown University
- Gillis, Justin (25 April 2006). "Cure for Neglected Diseases: Funding". The Washington Post.
- Isea, Raul (2010). "Identification of 11 potential malaria vaccine candidates using Bioinformatics". arXiv:1009.5956 [q-bio.GN].
- Dr. Manuel Elkin Patarroyo research team, Bogota, Colombia