Vaccines for pandemic influenza.Recent outbreaks of highly pathogenic avian influenza avian influenza: see influenza. in Asia and associated human infections have led to a heightened level of awareness and preparation for a possible influenza pandemic
1. a widespread epidemic of a disease. 2. widely epidemic. pan·dem·ic adj. Epidemic over a wide geographic area. n. virus could be prevented and severity of disease reduced. Production of live attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. and inactivated inactivated rendered inactive; the activity is destroyed. inactivated viruses treated so that they are no longer able to produce evidence of growth or damaging effect on tissue. vaccine seed viruses against avian influenza viruses, which have the potential to cause pandemics, and their testing in preclinical studies preclinical studies, n.pl a term used to describe research done before a clinical study. May be laboratory or epidemiologic research. and clinical trials will establish the principles and ensure manufacturing experience that will be critical in the event of the emergence of such a virus into the human population. Studies of such vaccines will also add to our understanding of the biology of avian influenza viruses and their behavior in mammalian hosts. ********** Influenza is a negative-strand RNA virus RNA virus n. Any of a group of viruses whose nucleic acid core is composed of RNA, including the picornaviruses, retroviruses, and paramyxoviruses. that belongs to the family Orthomyxoviridae, which consists of 4 genera genera, in taxonomy: see classification. : influenza A influenza A n. Influenza caused by infection with a strain of influenza virus type A. influenza A Infectious disease An avian virus, especially of ducks–which in China live near the pig reservoir and 'vector'; , influenza B influenza B n. Influenza caused by infection with influenza virus type B. influenza B Infectious disease An influenza virus which causes epidemics in 3-5 yr cycles. Cf Influenza A, Influenza C. , influenza C influenza C n. Influenza caused by infection with a strain of influenza virus type C. influenza C Infectious disease An influenza virus which causes nonepidemic, cold-like illness. Cf Influenza A, Influenza B. , and Thogoto viruses. The proteins of influenza A are encoded on 8 RNA RNA: see nucleic acid. RNA in full ribonucleic acid One of the two main types of nucleic acid (the other being DNA), which functions in cellular protein synthesis in all living cells and replaces DNA as the carrier of genetic gene segments. Influenza A viruses are widely distributed Adj. 1. widely distributed - growing or occurring in many parts of the world; "a cosmopolitan herb"; "cosmopolitan in distribution" cosmopolitan bionomics, environmental science, ecology - the branch of biology concerned with the relations between organisms in nature and can infect a wide variety of birds and mammals. Influenza A virus subtypes are classified on the basis of the antigenicity of their surface glycoproteins, hemagglutinin hemagglutinin /he·mag·glu·ti·nin/ (-gloo´ti-nin) an antibody that causes agglutination of erythrocytes. cold hemagglutinin one which acts only at temperatures near 4° C. (HA) and neuraminidase neuraminidase /neu·ra·min·i·dase/ (-ah-min´i-das) an enzyme of the surface coat of myxoviruses that destroys the neuraminic acid of the cell surface during attachment, thereby preventing hemagglutination. (NA); 16 HA and 9 NA subtypes are known to exist, and all of them infect aquatic birds. Most infections in waterfowl waterfowl, common term for members of the order Anseriformes, wild, aquatic, typically freshwater birds including ducks, geese, and screamers. In Great Britain the term is also used to designate species kept for ornamental purposes on private lakes or ponds, while in are not associated with clinical disease. Relatively few subtypes of influenza A viruses have caused sustained outbreaks of disease in the human population. Influenza A viruses of the H1, H2, and H3 HA and of the N1 and N2 NA subtypes have circulated in the human population in the 20th century. H1N1 viruses appeared in 1918 and circulated until 1957, when they were replaced by H2N2 viruses. H3N2 viruses appeared in 1968, replacing H2N2 viruses, and have remained in circulation in the human population. H1N1 viruses reappeared in the human population in 1977 and continue to cocirculate with H3N2 viruses (1). Currently, influenza epidemics in the winter are caused by H3N2 and H1N1 influenza A and influenza B viruses. Influenza Pandemics In addition to seasonal influenza epidemics, influenza pandemics have occurred periodically. An influenza pandemic occurs when an influenza strain with a novel HA subtype (programming) subtype - If S is a subtype of T then an expression of type S may be used anywhere that one of type T can and an implicit type conversion will be applied to convert it to type T. (with or without a novel NA subtype) appears and spreads in the human population, which has little or no immunity to the novel HA. In the 20th century, pandemics occurred in 1918, 1957, and 1968 and were associated with substantial illness and death. The pandemic of 1918, the "'Spanish flu," was caused by an influenza A virus of the H1N1 subtype and was responsible for [greater than or equal to] 40 million deaths worldwide (2). In the Asian influenza Asian influenza n. Influenza that is caused by a strain of influenza virus type A, which was first isolated in China during the 1957 epidemic. pandemic of 1957, in which H2N2 viruses appeared, influenza-associated excess deaths were estimated at >2 million worldwide (3). The influenza pandemic of 1968 started in Hong Kong Hong Kong (hŏng kŏng), Mandarin Xianggang, special administrative region of China, formerly a British crown colony (2005 est. pop. 6,899,000), land area 422 sq mi (1,092 sq km), adjacent to Guangdong prov. and was caused by an H3N2 virus. The 1968 pandemic virus had the same NA as the H2N2 virus it replaced but a novel HA. This pandemic was much less severe than the previous pandemics, with estimated influenza-associated excess deaths of [approximately equal to] 1 million (3). Preexisting pre·ex·ist or pre-ex·ist v. pre·ex·ist·ed, pre·ex·ist·ing, pre·ex·ists v.tr. To exist before (something); precede: Dinosaurs preexisted humans. v.intr. immunity to the N2 NA of the 1968 pandemic influenza virus influenza virus n. Any of three viruses of the genus Influenzavirus designated type A, type B, and type C, that cause influenza and influenzalike infections. may partially explain why this pandemic was less severe than the 2 preceding pandemics, although the availability of penicillins and macrolides may also have contributed. We cannot predict when the next influenza pandemic will occur, or which influenza virus subtype will cause it. Forecasts of the severity of the next influenza pandemic differ in their predictions of deaths based on the models used. Modeling based on the pandemic of 1968 projects 2 million-7.4 million excess deaths worldwide (3). Meltzer and colleagues have estimated that, in the absence of effective interventions, in the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. alone, the next influenza pandemic could cause 89,000-207,000 excess deaths and 314,000-734,000 hospitalizations, as well as tens of millions of outpatient visits and additional illnesses (4). In this scenario, the economic impact of an influenza pandemic would be severe. The economic costs due to deaths, illness, and hospitalizations in the United States alone, excluding disruptions to commerce and society, would be $71.3-$166.5 billion (4). In the recent H5N1 outbreaks in Asia, >120 million birds died or were culled during a 3-month period (3). For the countries of Thailand and Vietnam, the estimated decreases in gross domestic product (GDP GDP (guanosine diphosphate): see guanine. ) resulting from poultry farming poultry farming Raising birds commercially or domestically for meat, eggs, and feathers. Chickens, ducks, turkeys, and geese are the birds of primary commercial importance. Guinea fowl and squabs are chiefly of local interest. losses are $1.2 and $0.3 billion, respectively, with a total estimated loss in GDP for Asia of $10 to $15 billion, according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the same source. In addition to the effects on local poultry production and commerce, international trade and travel would undoubtedly suffer in an influenza pandemic. Avian avian /avi·an/ (a´ve-an) of or pertaining to birds. a·vi·an adj. Of, relating to, or characteristic of birds. Species as a Reservoir for Pandemic Influenza Viruses Aquatic birds are the reservoir for all known subtypes of influenza A viruses, and as such are the pool from which pandemic influenza viruses arise. Avian influenza (AI) viruses are introduced into the human population after reassortment with circulating human influenza A viruses or by directly infecting humans. Until 1997, it was widely believed that to infect humans an AI virus would have to undergo reassortment with a human influenza virus in an intermediate mammalian species to acquire the necessary characteristics for efficient transmission to and replication in humans. In the last 10 years, direct transmission of AI viruses from birds to humans has been reported on several occasions, causing a wide spectrum of disease, ranging from mild febrile febrile /feb·rile/ (feb´ril) pertaining to or characterized by fever. feb·rile adj. Of, relating to, or characterized by fever; feverish. and respiratory illness Noun 1. respiratory illness - a disease affecting the respiratory system respiratory disease, respiratory disorder adult respiratory distress syndrome, ARDS, wet lung, white lung - acute lung injury characterized by coughing and rales; inflammation of the in some H5 and H9N2 infections, conjunctivitis conjunctivitis (kənjəngtəvī`təs), inflammation or infection of the mucosal membrane that covers the eyeball and lines the eyelid, usually acute, caused by a virus or, less often, by a bacillus, an allergic reaction, or an in the case of H7 influenza infections, to severe disease and death, as seen in the current H5N1 outbreak in Asia. The details of these cases are given in Table 1. The gene segments of the influenza viruses isolated from the human H5N1 patients in 1997 were all derived from AI viruses, with no evidence of reassortment with human influenza viruses. Surveillance studies in birds in Hong Kong showed that H5N1 and H9N2 AI viruses co-circulated in poultry markets in Hong Kong at the time of the 1997 H5N1 AI outbreak, creating favorable conditions for reassortment (16). H9N2 AI viruses had become widespread in domestic chickens in Asia since 1990. In addition, both of these AI subtypes were isolated from ducks and geese in the region, suggesting a wide distribution in avian hosts. Data from phylogenetic phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history. studies led to the hypothesis that the H5N1 Hong Kong viruses acquired their HA gene from an A/goose/Guangdong/1/96-like (H5N1) virus and the gene encoding NA from an A/teal/Hong Kong/W312/97 (H6N1)-like virus circulating in terrestrial poultry. Data also suggested that H9N2 or H6N1 AI viruses circulating in the region were the likely source of the internal protein genes (17-20). H9N2 viruses continue to circulate in birds in southern China. The outbreak of human H5N1 cases in 1997 ended with the depopulation DEPOPULATION. In its most proper signification, is the destruction of the people of a country or place. This word is, however, taken rather in a passive than an active one; we say depopulation, to designate a diminution of inhabitants, arising either from violent causes, or the want of of the poultry markets in Hong Kong. These actions may have averted an influenza pandemic (16). Precursor viruses, however, continued to circulate in the region, and in 2003, highly pathogenic H5N1 viruses reemerged, and new human infections were identified and continue to be reported to be spoken of; to be mentioned, whether favorably or unfavorably. See also: Report to date. Preparing for the Next Pandemic The reemergence of highly pathogenic H5N1 AI viruses in Asia has raised concerns of a potential pandemic, resulting in an augmented level of preparedness for such an eventuality e·ven·tu·al·i·ty n. pl. e·ven·tu·al·i·ties Something that may occur; a possibility. eventuality Noun pl -ties . The pandemic preparedness plan for the United States was published in November 2005 (www.hhs. gov/pandemicflu/plan/). Two intervention strategies could prevent or lessen the severity of an emergent influenza pandemic, vaccination and use of antiviral drugs Antiviral Drugs Definition Antiviral drugs are medicines that cure or control virus infections. Purpose Antivirals are used to treat infections caused by viruses. . The use of antiviral antiviral /an·ti·vi·ral/ (-vi´ral) destroying viruses or suppressing their replication, or an agent that so acts. an·ti·vi·ral adj. compounds is discussed in another article in this issue (21). We focus on the challenges facing development of pandemic influenza vaccines and how we can prepare and test a library of vaccine seed viruses. Although the next influenza pandemic could possibly be caused by a different avian or reassortant virus than the highly pathogenic H5N1 AI virus now circulating in Asia, current vaccine development activities are largely focused on viruses of this subtype. Events in Asia underscore the urgent need for generating candidate H5N1 vaccines and evaluating them in humans, but ignoring AI viruses of the other subtypes would be imprudent im·pru·dent adj. Unwise or indiscreet; not prudent. im·pru  dent·ly adv. . All AI viruses are presumed to have
pandemic potential.Developing Vaccines for Pandemic Influenza Central to pandemic preparedness planning are effective vaccines to thwart the spread of a pandemic virus and to prevent illness and death associated with a novel virulent vir·u·lent adj. 1. Extremely infectious, malignant, or poisonous. Used of a disease or toxin. 2. Capable of causing disease by breaking down protective mechanisms of the host. Used of a pathogen. 3. strain. The principle behind the generation of human influenza vaccines is to elicit protective antibodies directed primarily against HA, the major protective antigen of the virus that induces neutralizing antibodies. Although major advances in our understanding of the biology and ecology of the H5N1 AI viruses have been made since human infections were first reported in 1997, and we have many years of experience and much accumulated knowledge about immunity to human influenza viruses, gaps remain in our understanding of immunity to AI viruses (Table 2). Filling in these gaps is vital to developing vaccines to protect the human population. Studies using inactivated vaccines against H9N2 and H5 subtypes of AI or purified recombinant H5 HA have demonstrated that these vaccines are poorly immunogenic im·mu·no·gen·ic adj. Producing an immune response. immunogenic producing immunity; evoking an immune response. in comparison to epidemic human influenza strains of the H1N1 and H3N2 subtypes. For example, inactivated vaccines against avian influenza subtypes require 2 doses and administration with adjuvant adjuvant /ad·ju·vant/ (aj?dbobr-vant) (a-joo´vant) 1. assisting or aiding. 2. a substance that aids another, such as an auxiliary remedy. 3. to achieve the desired level of neutralizing antibody (22-27) (Table 3). The precise antigenic properties of a nascent pandemic strain cannot be predicted, so available vaccines may be poorly antigenically matched to the pandemic virus. Practical considerations and hurdles for pandemic influenza vaccine development also have to be overcome. Manufacturing capacity, the ability of candidate vaccine strains to grow well in eggs, and biological safety containment of parent strains for vaccine development are all problems to be addressed. In addition, the most vulnerable sections of the population may not be the same as those seen with yearly influenza epidemics, making planning to target certain population groups for vaccination difficult at best. For these reasons, the time before the next pandemic must be used judiciously for developing and clinically testing candidate vaccines. Generating Vaccine Seed Viruses The interpandemic period must be used to explore the optimal scientific, manufacturing, regulatory, and clinical research strategies for developing vaccines that are effective against pandemic influenza so that a vaccine will be available as soon as possible in the event of a pandemic. To this end, the Laboratory of Infectious Diseases infectious diseases: see communicable diseases. , National Institute of Allergy and Infectious Diseases (NIAID NIAID National Institute of Allergy and Infectious Diseases. ), National Institutes of Health (NIH "Not invented here." See digispeak. NIH - The United States National Institutes of Health. ), is embarking on a program to develop candidate vaccines to prevent influenza pandemics caused by AI viruses. The vaccine seed viruses to be generated are based on the live attenuated cold-adapted influenza virus vaccines influenza virus vaccine n. A vaccine containing influenza virus, usually several strains of the virus, prepared in chick embryos and used to immunize against influenza. developed by Maassab and colleagues at the University of Michigan (body, education) University of Michigan - A large cosmopolitan university in the Midwest USA. Over 50000 students are enrolled at the University of Michigan's three campuses. The students come from 50 states and over 100 foreign countries. in the 1960s (28) and used as the basis for the FluMist vaccine (MedImmune, Inc., Gaithersburg, MD, USA) now licensed in the United States for persons 5-49 years of age for preventing interpandemic influenza. The principles of the development of such vaccines and safety and efficacy studies conducted in humans are reviewed elsewhere (29,30). The vaccine seed virus development strategy is not exclusive to live, attenuated vaccines, and similar studies with inactivated vaccines against different AI subtypes should be initiated. The goal of our research program is to establish the "proof of principle" that the A/AA/6/60 cold-adapted (AA ca) virus bearing AI virus HA and NA genes will be infectious, immunogenic, and sate in humans and therefore of potential use for controlling pandemic influenza. The observed efficacy of live, attenuated vaccines for human interpandemic influenza, together with the findings to date that inactivated or subunit sub·u·nit n. A subdivision of a larger unit. Noun 1. subunit - a monetary unit that is valued at a fraction (usually one hundredth) of the basic monetary unit fractional monetary unit AI vaccines are suboptimally immunogenic in humans, strongly suggests that using live vaccines against pandemic influenza is worth exploring. Live, attenuated AI vaccines might require fewer doses and might provide broader immune responses than inactivated or subunit vaccines. Live, attenuated influenza A candidate vaccines bearing the 6 internal genes of the AA ca donor virus (the attenuating genes) and the 2 protective HA and NA genes from human H3 or H1 viruses have been studied extensively in humans and have been licensed for general use. These vaccines are safe, infectious, immunogenic, nontransmissible, genetically stable, and efficacious ef·fi·ca·cious adj. Producing or capable of producing a desired effect. See Synonyms at effective. [From Latin effic (reviewed in [30]). It is reasonable to propose that a live, attenuated vaccine would rapidly induce protective immune responses, but this requires experimental verification in humans. The pandemic influenza vaccine candidates will be generated by plasmid-based reverse genetics reverse genetics methods such as antisense nucleic acids and site-directed mutagenesis that are used to selectively study gene function. Contrasts with classical genetics which depends on the isolation and analysis of cells (animals) with random mutations that can be identified. , shown in the Figure, panel A (reviewed in [31]). This technique allows infectious virus to be recovered from cells approved for use in human vaccine development (so-called qualified cells). These cells are cotransfected with plasmids encoding each of the 8 influenza gene segments to generate recombinant viruses that contain the HA and NA genes from AI viruses and 6 internal gene segments from the AA ca virus (31). Reverse genetics will allow modification of known virulence Virulence The ability of a microorganism to cause disease. Virulence and pathogenicity are often used interchangeably, but virulence may also be used to indicate the degree of pathogenicity. motifs in the HA or NA genes, such as the removal of the multibasic amino acid amino acid (əmē`nō), any one of a class of simple organic compounds containing carbon, hydrogen, oxygen, nitrogen, and in certain cases sulfur. These compounds are the building blocks of proteins. cleavage site cleavage site n. See restriction site. motif in the HA gene of highly pathogenic AI strains that is associated with virulence in birds (32). The other advantage of reverse genetics is that a selection system is not needed to derive appropriate reassortant viruses from a background of parental viruses. In addition, the plasmids encoding the genes from the attenuated vaccine donor strain are available, and only the HA and NA genes need to be cloned for each vaccine. Several H5N1 vaccine candidates have been developed by using this technique (33-36). Some potential obstacles to applying the reverse genetics approach include the need for qualified cells for virus production and intellectual property for this technique. However, as long as the HA and NA gene segments do not have to be modified, the 6-2 gene reassortant investigational pandemic vaccines can be generated by genetic reassortment, as shown in the Figure, panel B. A candidate H9N2 pandemic vaccine was generated by using this technique (37). [FIGURE OMITTED] Live, attenuated vaccines must be able to replicate to levels that elicit a protective immune response without causing disease in the host, so a balance of infectivity infectivity ability of an agent to infect. , level of attenuation Loss of signal power in a transmission. Attenuation The reduction in level of a transmitted quantity as a function of a parameter, usually distance. It is applied mainly to acoustic or electromagnetic waves and is expressed as the ratio of power densities. , and immunogenicity immunogenicity /im·mu·no·ge·nic·i·ty/ (-je-nis´it-e) the property enabling a substance to provoke an immune response, or the degree to which a substance possesses this property. must be achieved. Therefore, before the next pandemic, we must evaluate in humans the safety, infectivity, immunogenicity, and phenotypic phe·no·type n. 1. a. The observable physical or biochemical characteristics of an organism, as determined by both genetic makeup and environmental influences. b. stability of live, attenuated influenza A candidate vaccines. The types of in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. and in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. studies that will be performed before clinical trials in humans are initiated, in addition to standard safety tests, are listed in Table 4. In vitro studies will be performed to confirm the genome sequence of the vaccine viruses. The cold-adapted and temperature-sensitive phenotype phenotype (fē`nətīp'): see genetics. phenotype All the observable characteristics of an organism, such as shape, size, colour, and behaviour, that result from the interaction of its genotype (total genetic makeup) with of the vaccine viruses will be confirmed in vitro in tissue culture. The attenuation phenotype of the vaccine candidates must be tested in an appropriate animal model. A critical step in evaluating vaccine candidates is selecting a model in which restriction of replication of the vaccine virus can be convincingly demonstrated in comparison to the wild-type parent virus. Since we cannot predict how AI viruses of different subtypes will behave in different animal species, animal models for each virus subtype will be developed. The use of rodent rodent, member of the mammalian order Rodentia, characterized by front teeth adapted for gnawing and cheek teeth adapted for chewing. The Rodentia is by far the largest mammalian order; nearly half of all mammal species are rodents. models (e.g., mice and hamsters) will be explored. The use of a ferret model will be investigated as well, although limited availability When customers of the PSTN make telephone calls, they commonly make use of a telecommunications network called a switched-circuit network. In a switched-circuit network, devices known as switches are used to connect the caller to the callee. of influenza-seronegative ferrets and facilities in which highly pathogenic wild-type AI viruses can be evaluated in ferrets makes such studies logistically and practically difficult for assessing large numbers of candidate vaccines. In addition, the higher body temperature of the ferret may confound con·found tr.v. con·found·ed, con·found·ing, con·founds 1. To cause to become confused or perplexed. See Synonyms at puzzle. 2. interpretation of studies in which replication of temperature-sensitive viruses is being assessed. The vaccine viruses may also require evaluation in the standard Office International des Epizooties (World Organization for Animal Health) intravenous pathogenicity test in chickens to confirm that they are not highly pathogenic in chickens and, as such, do not pose a threat to the poultry industry. Such a requirement will be guided by national agricultural authorities. Immunogenicity, dose response, antibody response kinetics kinetics: see dynamics. Kinetics (classical mechanics) That part of classical mechanics which deals with the relation between the motions of material bodies and the forces acting upon them. , and efficacy studies will also be carried out in appropriate animal models before clinical trials. Past experience with live, attenuated vaccines for interpandemic human influenza (30) indicates that live virus vaccines may have great potential for use as vaccines during pandemic spread of influenza because of their high level of immunogenicity for immunologically naive persons and their ability to rapidly induce immunity, i.e., within the first 10 days after vaccination. The contribution of cellular immune responses cellular immune response n. See cell-mediated immune response. to the control of AI virus infection remains to be determined and can be examined in the context of live, attenuated vaccines. Such responses may be valuable in an influenza pandemic, in which the vaccine may protect from severe illness or death even if it is not completely antigenically matched to the emergent strain. Since a live, attenuated virus at·ten·u·at·ed virus n. A strain of a virus whose pathogenicity has been reduced so that it will initiate the immune response without producing the specific disease. vaccine based on the AA ca donor virus has been licensed by the Food and Drug Administration for general use in healthy persons 5-49 years of age, the infrastructure for manufacture and characterization of live, attenuated virus vaccines exists. The availability of the manufacturing capability for a live, attenuated virus vaccine makes it feasible to initiate a project in collaboration with industry to develop seed viruses for live, attenuated vaccines against influenza A viruses with pandemic potential. Our overall plan includes the following steps: 1) generation of a set of live, attenuated viruses bearing an H4-H16 HA and the accompanying NA found in the wild-type virus (we will not generate novel combinations of HA and NA proteins) on the attenuated AA ca donor virus background; 2) preparation and qualification of a clinical lot of each pandemic vaccine candidate; 3) evaluation of the safety, infectivity, immunogenicity, and phenotypic stability of each candidate vaccine in humans; 4) storage of human sera obtained from vaccinees to determine antigenic relatedness of the vaccine administered to the study participant with actual newly emerged pandemic viruses; and 5) storage of seed viruses for manufacture of vaccine to prevent disease caused by pandemic viruses that do emerge. Thus, vaccine manufacture can be initiated with pretested viruses without delay. Even if the seed virus does not match the pandemic strain and a vaccine virus that is an exact match has to be generated, the dosing and immunogenicity data from the previous vaccine studies can guide its use. If the AA ca reassortant virus is safe and attenuated but infectious in humans, it can be used as a challenge virus to assess vaccine efficacy Vaccine efficacy is defined as the reduction in the incidence of a disease among people who have received a vaccine compared to the incidence in unvaccinated people. The efficacy of a new vaccine is measured in phase III clinical trials by giving one group of people a vaccine and for both live and inactivated influenza virus vaccines. A major concern associated with using a live, attenuated influenza vaccine bearing genes derived from an AI virus is the risk for reassortment of the vaccine virus with a circulating influenza virus. This reassortment could result in a novel subtype of influenza that could spread in the human population. Although such an event may not be of concern in the face of widespread disease from a pandemic strain of influenza, it would clearly be an unfavorable outcome if the threatened pandemic did not materialize. Clinical trials in humans of these live, attenuated pandemic vaccine candidates will be performed in carefully planned and executed inpatient studies. The risk for reassortment must be carefully considered by public health authorities before a decision is made to introduce a live, attenuated vaccine in a threatened pandemic. Using every available option to develop vaccines that may be used for an influenza pandemic is critical. Conclusions Recent events in Asia have led to intensive planning and preparation for a potential global influenza pandemic. Vaccine development is a critical part of preparedness. Recent studies that used mathematical models to study potential intervention strategies predicted that local pre-vaccination with a vaccine that is 70% efficacious against the pandemic strain could enhance the effectiveness of antiviral prophylaxis prophylaxis (prō'fĭlăk`sĭs), measures designed to prevent the occurrence of disease or its dissemination. Some examples of prophylaxis are immunization against serious diseases such as smallpox or diphtheria; quarantine to confine in preventing spread of the virus (38). Production and establishment of the proof of principle of candidate live and inactivated vaccines with AI HA and NA proteins in the interpandemic period could save valuable time in the event of a pandemic. Such studies will also provide information about the biology of AI viruses and immune responses to them in humans. This research was supported in part by the Intramural intramural /in·tra·mu·ral/ (-mu´r'l) within the wall of an organ. in·tra·mu·ral adj. 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Pandemic preparedness: lessons learnt from H2N2 and H9N2 candidate vaccines. Med Microbiol Immunol. 2002;191:203-8. (23.) Stephenson I, Nicholson KG, Gluck R, Mischler R. Newman RW, Palache AM, et al. Safety and antigenicity of whole virus and subunit influenza A/Hong Kong/1073/99 (H9N2) vaccine in healthy adults: phase I randomised Adj. 1. randomised - set up or distributed in a deliberately random way randomized irregular - contrary to rule or accepted order or general practice; "irregular hiring practices" trial. Lancet. 2003;362:1959-66. (24.) Nicholson KG. Colegate AE, Podda A, Stephenson I, Wood J, Ypma E, et al. Safety and antigenicity of non-adjuvanted and MF59-adjuvanted influenza A/Duck/Singapore/97 (H5N3) vaccine: a randomised trial of two potential vaccines against H5N1 influenza. Lancet. 2001;357:1937-43. (25.) Stephenson I, Nicholson KG, Colegate A, Podda A, Wood J, Ypma E, et al. Boosting immunity to influenza H5N1 with ME59-adjuvanted H5N3 A/Duck/Singapore/97 vaccine in a primed human population. Vaccine. 2003;21:1687-93. (26.) Stephenson 1, Bugarini R, Nicholson KG, Podda A, Wood JM, Zambon MC, et al. Cross-reactivity to highly pathogenic avian influenza H5N1 viruses after vaccination with nonadjuvanted and MF59-adjuvanted influenza A/Duck/Singapore/97 (H5N3) vaccine: a potential priming strategy. J Infect Dis. 2005:191:1210-5. (27.) Treanor JJ, Wilkinson BE. Masseoud F. Hu-Primmer J, Battaglia R, O'Brien D, et al. Safety and immunogenicity of a recombinant hemagglutinin vaccine for H5 influenza in humans. Vaccine. 2001;19:1732-7. (28.) Maassab HF, Bryant ML. The development of live attenuated cold-adapted influenza virus vaccine for humans. Rev Med Virol. 1999;9:2374-4. (29.) Murphy BR. Use of live attenuated cold-adapted influenza reassortant virus vaccines in infants, children, young adults and elderly adults. Infect Dis Clin Pract. 1993;2:174-81. (30.) Murphy BR, Coelingh K. Principles underlying the development and use of live attenuated cold-adapted influenza A and B virus vaccines. Viral Immunol. 2002;15:295-323. (31.) Subbarao K, Katz JM. Influenza vaccines generated by reverse genetics. Curr Top Microbiol Immunol. 2004:283:3134-2. (32.) Horimoto T, Kawaoka Y. Reverse genetics provides direct evidence lor a correlation of hemagglutinin cleavability and virulence of an avian influenza A virus. J Virol. 1994;68:3120-8. (33.) Subbarao K, Chen H, Swayne D, Mingay L, Fodor E, Brownlee G, et al. Evaluation of a genetically modified genetically modified Adjective (of an organism) having DNA which has been altered for the purpose of improvement or correction of defects genetically modified genetic adj [food etc] → reassortant H5N1 influenza A virus vaccine candidate generated by plasmid-based reverse genetics. Virology. 2003:305:192-200. (34.) Webby See WBI. RJ, Perez DR, Coleman JS, Guan Y, Knight JH, Govorkova LA, et al. Responsiveness to a pandemic alert: use of reverse genetics for rapid development of influenza vaccines. Lancet. 2004;363:1099-103. (35.) Lipatov AS, Webby RJ, Govorkova EA, Krauss S, Webster RG. Efficacy of H5 influenza vaccines produced by reverse genetics in a lethal mouse model. J Infect Dis. 2005;191:1216-20. (36.) Nicolson C, Major D, Wood JM, Robertson JS. Generation of influenza vaccine viruses on Vero cells by reverse genetics: an H5N1 candidate vaccine strain produced under a quality system. Vaccine. 2005;23:2943-52. (37.) Chen H, Matsuoka Y, Swayne D, Chen Q, Cox NJ, Murphy BR, et al. Generation and characterization of a cold-adapted influenza A H9N2 reassortant as a live pandemic influenza virus vaccine candidate. Vaccine. 2003:21:4430-6. (38.) Longini IM Jr, Nizam A, Xu S, Ungchusak K, Hanshaoworakul W, Cummings DA, et al. Containing pandemic influenza at the source. Science. 2005:309:1083-7. Address for correspondence: Kanta Subbarao, Laboratory of Infectious Diseases, NIAID, NIH, Bldg 50, Rm 6132, 50, South Dr, Bethesda, MD 20892, USA: fax: 401-496-8312; email: ksubbarao@niaid.nih.gov The opinions expressed by authors contributing to this journal do not necessarily reflect the opinions ot" the Centers for Disease I Control and Prevention or the institutions with which the authors are affiliated. Catherine J. Luke * and Kanta Subbarao * * National Institutes of Health, Bethesda, Maryland Bethesda is an urbanized, but unincorporated, area in southern Montgomery County, Maryland, just Northwest of Washington, D.C. It takes its name from a church located there, the Bethesda Presbyterian Church, built in 1820 and rebuilt in 1850, which in turn took its name from , USA Dr Luke is a regulatory officer in the Laboratory of infectious Diseases, NIAID, NIH, where she is working on the development of vaccines against pandemic influenza. Dr Subbarao is a senior investigator in the Laboratory of Infectious Diseases, NIAID, NIH. Her research is focused on the development of vaccines against pandemic strains of influenza and the development of animal models and evaluation of vaccines against the severe acute respiratory syndrome-associated coronavirus coronavirus /co·ro·na·vi·rus/ (ko-ro´nah-vi?rus) any virus belonging to the family Coronaviridae. Coronavirus /Co·ro·na·vi·rus/ (ko-ro´nah-vi?rus .
Table 1. Direct transmission of avian influenza viruses to humans
Virus No. cases
subtype Year Location (no. deaths)
H5N1 1997 Hong Kong 18 (6)
H9N2 1999 Hong Kong 2 (0)
H9N2 1999 Guangdong Province, 5 (0)
China
H9N2 2003 Hong Kong 1 (0)
H5N1 2003 Hong Kong 2 (l)
H7N7 2003 Netherlands 89 (l)
H10N7 2004 Egypt 2 (0)
H5N1 2003- Asia (Vietnam, 116 (60) *
present Thailand, Cambodia,
Virus
subtype Clinical features Notes
H5N1 Associated with outbreak of
highly pathogenic AI in
poultry in the region
H9N2 Mild influenzalike illness
H9N2 Mild influenzalike illness
H9N2 Mild influenzalike illness
H5N1 Primary viral pneumonia, 7-year-old girl died in
lymphopenia, respiratory Fujian Province, China,
distress and H5N1 infection was not
confirmed. Her
33-year-old father died
from confirmed H5N1
influenza infection in Hong
Kong, and her 8-year-old
brother recovered from
H5N1 infection.
H7N7 Conjunctivitis (78 cases), Most cases were in persons
mild influenzalike involved in handling poultry
symptoms (2 cases) or (86), with 3 family members
both (5 cases). In fatal also affected.
case, pneumonia followed
by respiratory distress
syndrome
H10N7 Fever and cough Both cases were in infants,
who recovered without
complications
H5N1 Fever, respiratory Human cases concomitant
symptoms, lymphopenia, with unprecedented
elevated liver enzymes. outbreaks of highly
Severe cases progress to pathogenic H5N1 AI in
respiratory failure, multiple poultry
organ dysfunction, and
death.
Virus
subtype Reference(s)
H5N1 (5,6)
H9N2 (7)
H9N2 (8)
H9N2 (9)
H5N1 (10)
H7N7 (11)
H10N7 (12)
H5N1 WHO *
(13-15)
* WHO, World Health Organization. As of September 29, 2005.
Source: http://www.who.int/csr/disease/avian_influenza/country/en
Table 2. Challenges for developing vaccines for pandemic influenza:
knowns and unknowns *
What we know from experience with What we don't know
human influenza viruses
Antibodies against the HA (and to Which avian influenza virus will
a lesser extent NA) are critical cross species barrier to cause a
for protection. pandemic
Systemic immune response is strain Importance of antigenic drift
specific. among avian influenza viruses
Mucosal immune response provides Immunogenicity of HA of avian
broader cross-protection. viruses in humans (unknown or
poor)
Cellular immunity is needed for
viral clearance.
Vaccine strain must closely match
the circulating strain.
* HA, hemagglutinin; NA, neuraminidase.
Table 3. Details of clinical trials in humans of inactivated and
subunit vaccines against avian influenza
Target
virus
subtype Description of vaccine candidate Adjuvant
H9N2 Inactivated whole virus (A/HK/1073/99). 7.5, Aluminum
3.8, 1.9 [micro]g/dose with adjuvant or 15 hydroxide
[micro]g without adjuvant. 2 doses, day 0 and
day 21
H9N2 H9N2 whole virus or subunit vaccine. 7.5, 15, None
or 30 [micro]g per dose. 2 doses, day 0 and
day 21.
H5N1 Low pathogenicity H5N3 strain MF59
(A/duck/Singapore/F1 19-3/97) subunit vaccine
with or without adjuvant. 7.5, 15, 30
[micro]g per dose. 2 doses, day 0, day 21
H5N1 Purified baculovirus-expressed recombinant None
H5 HA derived from A/HK/156/97. 25, 45, 90
[micro]g per dose, 2 doses or 1 dose of 90
[micro]g followed by 10-[micro]g dose
Target
virus
subtype Findings Reference
H9N2 Two doses needed to achieve HI * antibody (22)
titer of [greater than or equal to]
1:40 at any dose.
H9N2 Two doses needed to achieve HI titer of (23)
[greater than or equal to] 1:40 in
persons <32 years of age, 1 dose needed to
achieve HI titer of [greater than or
equal to] 1:40 in persons >32 y of age.
H5N1 Geometric mean antibody and (24)
seroconversion rates significantly higher
when vaccine administered with adjuvant; 2
doses of vaccine needed to achieve
antibody responses indicative of protection.
H5N1 23% of volunteers had neutralizing titers of (27)
[greater than or equal to] 1:80 after a single
dose of 90 [micro]g; 52% of volunteers had
neutralizing antibody titers after 2
doses of 90 [micro]g.
* HI, hemagglutination inhibition.
Table 4. Preclinical testing to be performed on live attenuated
pandemic influenza vaccine candidates
In vitro testing In vivo testing
Confirmation of virus genome Intravenous pathogenicity test
sequence in chickens
Trypsin-dependent replication in Attenuation (restricted
cell culture replication) in rodent or
ferret model
Confirmation of phenotype Immunogenicity in rodent or
associated with the vaccine donor ferret model
virus, e.g., temperature Protective efficacy in rodent
sensitivity, cold adaptation model
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