Correlates of immune protection induced by live, attenuated, cold-adapted, trivalent, intranasal influenza virus vaccine

Intranasal administration of a proteosome-influenza vaccine is well-tolerated and induces serum and nasal secretion influenza antibodies in healthy human subjects

Two randomized, blinded, active comparator-controlled trials of a prototype monovalent A/Beijing/262/95 (H1N1) - proteosome vaccine delivered by intranasal spray were performed in healthy adults. Overall, the intranasal proteosome-adjuvanted vaccine was well-tolerated with only mild stuffy nose and rhinorrhea seen more frequently in recipients of vaccine than in recipients of intranasal saline, and there were no serious adverse events. The intranasal proteosome-adjuvanted vaccine induced serum hemagglutination inhibiting (HAI) and nasal secretory IgA (sIgA) responses specific for the influenza antigen. Serum HAI responses were most influenced by the dosage level, whereas mucosal sIgA responses, although demonstrable with both single-dose and two-dose vaccine regimens, appeared to be greater in response to two-dose regimens (regardless of dose level). Further evaluation of mucosal influenza immunization using the proteosome adjuvant/delivery system is clearly warranted.

Can successful vaccines teach us how to induce efficient protective immune responses?

Some recently introduced vaccines that have excellent efficacy records have been developed without a clear understanding of their mechanism of protection. In fact, successful vaccines have often emerged out of empirical observations and have only rarely been the result of a rational use of the continuously increasing immunological knowledge available to scientists. However, a posteriori deciphering of the biological bases for the efficacy of successful vaccines should be an essential component of research efforts directed at the development of new vaccines for the most challenging infectious diseases.

Immune responses and protective efficacy in ponies immunised with an equine influenza ISCOM vaccine containing an 'American lineage' H3N8 virus

Protective responses generated by vaccination with an immuno-stimulating complex (ISCOM)-based vaccine for equine influenza (EQUIP F), containing a new 'American lineage' H3N8 virus, were studied. Seven ponies in the vaccine group received two intramuscular injections of EQUIP F given 6 weeks apart. Aerosol challenge with an A/eq/Newmarket/1/93 reference strain 4 weeks after booster vaccination resulted in clinical signs of infection and viral shedding in 7 influenza-naive control animals whereas the vaccinated ponies were significantly protected from both clinical signs and virus excretion. Influenza virus-specific IgG responses in serum following immunisation with the ISCOM vaccine were predominantly of the IgGa and IgGb sub-isotypes, a pattern similar to that generated by equine influenza virus infection. However, in contrast to the response following infection, virus-specific antibody responses in nasal washes following immunisation were characterised by the presence of IgG but not IgA.These results demonstrated that an ISCOM-based vaccine containing A/eq/Kentucky/98 provides strong protective immunity against challenge with an 'American lineage' H3N8 reference virus.

Finding optimal vaccination strategies for pandemic influenza using genetic algorithms

In the event of pandemic influenza, only limited supplies of vaccine may be available. We use stochastic epidemic simulations, genetic algorithms (GA), and random mutation hill climbing (RMHC) to find optimal vaccine distributions to minimize the number of illnesses or deaths in the population, given limited quantities of vaccine. Due to the non-linearity, complexity and stochasticity of the epidemic process, it is not possible to solve for optimal vaccine distributions mathematically. However, we use GA and RMHC to find near optimal vaccine distributions. We model an influenza pandemic that has age-specific illness attack rates similar to the Asian pandemic in 1957-1958 caused by influenza A(H2N2), as well as a distribution similar to the Hong Kong pandemic in 1968-1969 caused by influenza A(H3N2). We find the optimal vaccine distributions given that the number of doses is limited over the range of 10-90% of the population. While GA and RMHC work well in finding optimal vaccine distributions, GA is significantly more efficient than RMHC. We show that the optimal vaccine distribution found by GA and RMHC is up to 84% more effective than random mass vaccination in the mid range of vaccine availability. GA is generalizable to the optimization of stochastic model parameters for other infectious diseases and population structures.

Population-wide benefits of routine vaccination of children against influenza

Using a stochastic simulation model of influenza transmission, clinical illness, and economic costs, we estimated the population-wide benefits of routinely vaccinating US children (ages 6 months to 18 years) against influenza. Disease burden was projected to decline as a result of both reduced susceptibility to infection among vaccinees and reductions in disease transmission to others in the community. Vaccination of 20% of children would reduce the total number of influenza cases in the US by 46%; 80% coverage would reduce the total number of cases by 91%. Similar reductions were estimated to occur in influenza-related mortality and economic costs.

Role of influenza vaccine for healthy children in the US

Influenza infection is associated with significant morbidity and mortality in adults, but the highest attack rates for influenza regularly occur in children, particularly those in preschool and elementary school. The consequences of influenza in this younger population - increased rate of hospitalization in those younger than 2 years of age and serious associated morbidity - have been underestimated. Children are also the critical link for spreading influenza in the community. Recent data suggest that mass influenza vaccination of healthy children would not only protect recipients, but also may reduce the burden of influenza throughout the community. During the past 3 decades, efforts to control influenza have focused on the use of an injectable trivalent inactivated vaccine (TIV) in high-risk persons. The vaccine is 'safe' and effective, but its acceptance and uptake by patients and healthcare providers have been modest at best. A new intranasal, live-attenuated, trivalent cold-adapted influenza virus vaccine (CAIV-T) [FluMist] is 'safe', well tolerated, immunogenic, and efficacious in preventing influenza illness in healthy children. Compared with TIV, CAIV-T is easier to administer and should be more readily acceptable, particularly for mass immunization campaigns. CAIV-T also induces a broader immune response and has demonstrated protection against at least three different variant influenza strains. This vaccine is particularly well suited for routine immunization of children and thus offers the potential for greatly improved control of influenza. However, the acquisition cost per single dose of FluMist for the 2003-4 season ( approximate, equals 46 US dollars) significantly hampered its uptake both by practitioners and by managed care organizations, even despite a later approximate, equals 25 US dollars rebate offer. For the 2004-5 season, CAIV-T is likely to be only modestly more expensive (average wholesale price: 16.50 US dollars for non-returnable doses, 23 US dollars for returnable doses) than TIV. The practitioner must consider the benefits of FluMist compared with its likely higher vaccine cost and the issues of reimbursement among multiple insurers.

Safety and immunogenicity of adenovirus-vectored nasal and epicutaneous influenza vaccines in humans

The increasing number and density of the human population, the emergence of lethal influenza strains, and the potential use of designer influenza virus as a bioweapon, collectively highlight a critical need for more rapid production of influenza vaccines and less invasive means of delivery. We have developed a nonreplicative adenovirus-vectored influenza vaccine that can be produced without the prerequisite of growing influenza virus. This new class of vaccines can be administered as a nasal spray or skin patch by personnel without medical training. We report here that adenovirus-vectored nasal and epicutaneous influenza vaccines were well tolerated by human volunteers. The nasal vaccine was more potent than its epicutaneous counterpart under the adjuvant-free experimental condition. These results provide the foundation for further human testing of needleless vectored vaccines as promising alternatives to current vaccines.

Predicting antigenic variants of influenza A/H3N2 viruses

Models based on amino acid changes in influenza hemagglutinin protein were compared to predict antigenic variants of influenza A/H3N2 viruses.

Current inactivated influenza vaccines provide protection when vaccine antigens and circulating viruses share a high degree of similarity in hemagglutinin protein. Five antigenic sites in the hemagglutinin protein have been proposed, and 131 amino acid positions have been identified in the five antigenic sites. In addition, 20, 18, and 32 amino acid positions in the hemagglutinin protein have been identified as mouse monoclonal antibody–binding sites, positively selected codons, and substantially diverse codons, respectively. We investigated these amino acid positions for predicting antigenic variants of influenza A/H3N2 viruses in ferrets. Results indicate that the model based on the number of amino acid changes in the five antigenic sites is best for predicting antigenic variants (agreement = 83%). The methods described in this study could be applied to predict vaccine-induced cross-reactive antibody responses in humans, which may further improve the selection of vaccine strains.

Immunogenicity and protection efficacy of replication-deficient influenza A viruses with altered NS1 genes

We explored the immunogenic properties of influenza A viruses with altered NS1 genes (NS1 mutant viruses). NS1 mutant viruses expressing NS1 proteins with an impaired RNA-binding function or insertion of a longer foreign sequence did not replicate in murine lungs but still were capable of inducing a Th1-type immune response resulting in significant titers of virus-specific serum and mucosal immunoglobulin G2 (IgG2) and IgA, but with lower titers of IgG1. In contrast, replicating viruses elicited high titers of serum and mucosal IgG1 but less serum IgA. Replication-deficient NS1 mutant viruses induced a rapid local release of proinflammatory cytokines such as interleukin-1beta (IL-1beta) and IL-6. Moreover, these viruses also elicited markedly higher levels of IFN-alpha/beta in serum than the wild-type virus. Comparable numbers of virus-specific primary CD8(+) T cells were determined in all of the groups of immunized mice. The most rapid onset of the recall CD8(+)-T-cell response upon the wild-type virus challenge was detected in mice primed with NS1 mutant viruses eliciting high levels of cytokines. It is noteworthy that there was one NS1 mutant virus encoding NS1 protein with a deletion of 40 amino acids predominantly in the RNA-binding domain that induced the highest levels of IFN-alpha/beta, IL-6 and IL-1beta after infection. Mice that were immunized with this virus were completely protected from the challenge infection. These findings indicate that a targeted modification of the RNA-binding domain of the NS1 protein is a valuable technique to generate replication-deficient, but immunogenic influenza virus vaccines.

Safety, immunogenicity and efficacy of intranasal, live attenuated influenza vaccine

Data supporting the use of the live attenuated influenza vaccine (LAIV) in children and adults is reviewed, and the development and characteristics of the vaccine are summarized. The vaccine is highly effective and well tolerated in children and adults from 5 to 49 years of age. Correlates of immune protection include serum hemagglutination-inhibition antibody and secretory immunoglobulin A. Efficacy against antigenically well-matched epidemic influenza strains was high at 92%. In 1 year, despite a significant antigenic change in the epidemic influenza virus that did not match the vaccine, LAIV conferred 86% protection against culture-confirmed illness in children. In the future it is expected that additional studies will support a broadening of the age range for use with the LAIV to prevent influenza in children and adults.

Live attenuated influenza vaccine induces cross-reactive antibody responses in children against an a/Fujian/411/2002-like H3N2 antigenic variant strain

Serum antibody titers against the A/Panama/2007/99(H3N2) and A/Fujian/411/2002(H3N2)-like viruses were determined in children 6-35 months of age who received either 1 dose of the inactivated influenza vaccine or the live attenuated influenza vaccine containing the A/Panama strain. Results indicated that the live vaccine induced higher antibody responses than the inactivated vaccine against the A/Panama and A/Fujian-like viruses.

Trivalent Intranasal Influenza Vaccine, Live

OBJECTIVE

To review human data on the efficacy, safety, and clinical use of trivalent intranasal influenza vaccine, live (TIIVL).

DATA SOURCES

A MEDLINE search (1966–3rd week of January 2004) using the terms influenza vaccine, intranasal administration, and FluMist was conducted. References from pertinent articles were also reviewed.

STUDY SELECTION AND DATA EXTRACTION

Studies conducted in humans and published in English were selected. Double-blind, controlled trials evaluating the efficacy and safety of TIIVL were evaluated.

DATA SYNTHESIS

Administration of TIIVL results in mucosal and humoral immunity to influenza. Results of clinical trials in children and adults have demonstrated that TIIVL reduces the incidence of influenza. In children, TIIVL was also associated with a decrease in febrile illness and febrile otitis media. In adults, reductions in workday absences and medical visits due to febrile upper respiratory tract illness were also documented. TIIVL is well tolerated, with rhinorrhea or nasal congestion and sore throat occurring more frequently than with placebo.

CONCLUSIONS

TIIVL is an alternative to intramuscular inactivated influenza vaccine in healthy individuals between 5 and 49 years of age. However, the vaccine is contraindicated in the majority of patient populations for whom annual influenza vaccination is recommended. THIS ARTICLE IS APPROVED FOR CONTINUING EDUCATION CREDIT ACPE UNIVERSAL PROGRAM NUMBER: 407-000-04-037-H01

Measuring antibody responses to a live attenuated influenza vaccine in children

BACKGROUND

Hemagglutination inhibition (HAI) assay is the standard method for evaluating inactivated influenza vaccines, but no standard assay has been established for evaluating live attenuated influenza vaccines (LAIV). LAIV containing A/Beijing/262/95(H1N1) induced low serum HAI antibody responses to the antigenic variant, A/New Caledonia/20/99(H1N1) in a serologic study but provided protection against the A/New Caledonia-like viruses in a community study. Neutralization and HAI assays were compared by measuring H1N1 cross-reactive antibody responses to the LAIV in children.

METHODS

Sera were collected from 50 children 1-8 years of age before vaccination and 4-6 weeks after each dose of the LAIV. Antibody titers to the 3 vaccine viruses were measured by the HAI assay, whereas antibody titers against the H1N1 vaccine virus (A/Beijing/262/95) and 2 H1N1 antigenic variants (A/Shenzhen/227/95 and A/New Caledonia/20/99) were measured by the HAI and neutralization assays.

RESULTS

Initially seronegative participants were more likely to develop HAI seroconversion responses to the 3 vaccine viruses than the baseline seropositive participants (77% versus 14% for H1N1, 100% versus 20% for H3N2, 100% versus 19% for B, P < 0.01, Fisher's exact test). For the H1N1 cross-reactive antibody responses, seroconversion rates measured by the neutralization assay were significantly higher than those measured by the HAI assay (95% versus 78%, P = 0.0485 for A/Beijing/262/95; 75% versus 24%, P < 0.0001 for A/Shenzhen/227/95; 51% versus 5%, P < 0.0001 for A/New Caledonia/20/99).

CONCLUSIONS

The neutralization assay was more sensitive than the HAI assay for measuring H1N1 antibody responses after vaccination of children with the LAIV and may provide a better correlate of clinical protection provided by the LAIV.

New vaccines for old diseases: trivalent cold-adapted influenza vaccine

Schoolchildren regularly have the highest influenza attack rates. Schoolchildren also are accessible for vaccination; school-based vaccine clinics can facilitate delivery of vaccine to a high proportion of children in a short period of time. CAIV-T has advantages for immunization of this group due to the effectiveness of a single dose, ease of administration, and ready acceptance by children. Modeling of control for an influenza epidemic by Longini et al. has shown vaccination of 70% of school children would dampen epidemics and significantly reduce the exposure of vulnerable people in the community. The goal of the central Texas trial is to demonstrate this effect in the field. Universal childhood immunization could be an important supplement to current control efforts. Vaccine coverage with TIV has leveled off since 1997; no progress toward the Healthy People 2010 goals of 90% coverage has been made after 4 years in the new decade. The number of excess deaths is expected to double within the next 25 years if control methods are not intensified. CAIV-T may become an important adjunct to control measures and can facilitate influenza pandemic preparedness.

Role of IgA versus IgG in the Control of Influenza Viral Infection in the Murine Respiratory Tract

The roles of IgG and secretory IgA in the protection of the respiratory tract (RT) against influenza infection remain unclear. Passive immunization with Ab doses resulting in serum IgG anti-influenza virus Ab titers far in excess of those observed in immune mice has compounded the problem. We compared the effects of i.v. anti-influenza virus IgG and i.v. anti-influenza virus polymeric IgA (pIgA) mAb administered in amounts designed to replicate murine convalescent serum or nasal Ab titers, respectively. A serum anti-influenza virus IgG titer 2.5 times the normal convalescent serum anti-influenza virus IgG titer was required for detectible Ab transudation into nasal secretions, and a serum IgG titer 7 times normal was needed to lower nasal viral shedding by 98%. Anti-influenza virus pIgA at a nasal Ab titer comparable to that seen in convalescent mice eliminated nasal viral shedding. The RT of influenza-infected pIgA- or IgG-protected mice were studied by scanning electron microscopy. Only pIgA was found to prevent virally induced pathology in the upper RT, suggesting that IgG did not prevent viral infection of the nose, but neutralized newly replicated virus after infection had been initiated. In contrast, IgG, but not pIgA, was found to prevent viral pathology in the murine lung. Our results help to resolve the controversy of IgA- vs IgG-mediated protection of the RT; both Abs are important, with plasma IgG Ab serving as the back-up for secretory IgA-mediated protection in the nasal compartment, and IgG being the dominant Ab in protection of the lung.

Current status of live attenuated influenza virus vaccine in the US

The efficacy and effectiveness of cold adapted live attenuated (CAIV-T, FluMist intranasal influenza vaccine is reviewed. CAIV-T consists of approximately 10(7) TCID50 per dose of each influenza A/H1N1, influenza A/H3N2, and influenza B vaccine strain. The exact strains are updated each year to antigenically match the antigens recommended by national health authorities for inclusion in the vaccine. In one year in which the vaccine strain did not well match the epidemic strain, the live attenuated vaccine induced a broad immune response that cross-reacted significantly with the drifted strain. The efficacy of CAIV-T in adults was demonstrated with challenge studies and the effectiveness of the vaccine for reducing febrile upper respiratory illness, days of missed work, and days of antibiotic use was demonstrated in a large field trial. In young children, protective efficacy against culture confirmed influenza was demonstrated in a field trial with overall protective efficacy of 92% during a two year study. Vaccine was also highly protective against a strain not contained in the vaccine, with 86% protective efficacy demonstrated against this significantly drifted virus. Effectiveness measures, including protection against febrile otitis media and visits to the doctor were demonstrated. Live attenuated vaccine provides a significant new tool to help prevent influenza.

Recommendations for influenza immunization of children

Epidemiologic studies indicate that children of all ages with certain chronic conditions and otherwise healthy children younger than 24 months of age are hospitalized for influenza infection and its complications at high rates similar to those experienced by the elderly. Annual influenza immunization is recommended for all children with high-risk conditions who are 6 months of age and older. Young, healthy children are at high risk of hospitalization for influenza infection; therefore, the American Academy of Pediatrics recommends influenza immunization for healthy children 6 through 24 months of age, for household contacts and out-of-home caregivers of all children younger than 24 months of age, and for health care professionals. To protect these children more fully against the complications of influenza, increased efforts are needed to identify all high-risk children and inform their parents when annual immunization is due. The purposes of this statement are to update recommendations for routine use of influenza vaccine in children and to review the indications for use of trivalent inactivated influenza vaccine and live-attenuated influenza vaccine.

Influenza virus vaccine live intranasal--MedImmune vaccines: CAIV-T, influenza vaccine live intranasal

MedImmune Vaccines (formerly Aviron) has developed a cold-adapted live influenza virus vaccine [FluMist] that can be administered by nasal spray. FluMist is the first live virus influenza vaccine and also the first nasally administered vaccine to be marketed in the US. The vaccine will be formulated to contain live attenuated (att) influenza virus reassortants of the strains recommended by the US Public Health Service for each 'flu season. The vaccine is termed cold-adapted (ca) because the virus has been adapted to replicate efficiently at 25 degrees C in the nasal passages, which are below normal body temperature. The strains used in the seasonal vaccine will also be made temperature sensitive (ts) so that their replication is restricted at 37 degrees C (Type B strains) and 39 degrees C (Type A strains). The combined effect of the antigenic properties and the att, ca and ts phenotypes of the influenza strains contained in the vaccine enables the viruses to replicate in the nasopharynx to produce protective immunity. The original formulation of FluMist requires freezer storage throughout distribution. Because many international markets do not have distribution channels well suited to the sale of frozen vaccines, Wyeth and MedImmune are collaborating to develop a second generation, refrigerator-stable, liquid trivalent cold-adapted influenza vaccine (CAIV-T), which is in phase III trials. Initially, the frozen formulation will only be available in the US. For the 2003-2004 season, FluMist will contain A/New Caledonia/20/99 (H1N1), A/Panama/2007/99 (H3N2) (A/Moscow/10/99-like) and B/Hong Kong/330/2001. Aviron was acquired by MedImmune on 15 January 2002. Aviron is now a wholly-owned subsidiary of MedImmune and is called MedImmune Vaccines. Aviron acquired FluMist in March 1995 through a Co-operative Research and Development Agreement (CRADA) with the US NIAID, and a licensing agreement with the University of Michigan, Ann Arbor, USA. In June 2000, the CRADA was extended through to June 2003. Aviron holds exclusive worldwide rights to the vaccine except for Japan, where Kaketsuken Pharmaceuticals (also known as Chemo-Sero-Therapeutic Research Institute) is the licensee. Aviron signed a development and licensing agreement with Sang-A in Korea, which was to manufacture and market FluMist in South Korea. However, in 2000, Aviron terminated all rights and licences to Sang-A relating to FluMist. Sang-A responded by filing a suit against Aviron in August 2000, for breach of contract and unfair and deceptive business practices. Aviron filed a counter claim denying the allegations in late Sept 2001. In 1999, Aviron entered into an agreement with Wyeth-Lederle Vaccines for worldwide collaboration in the marketing of FluMist. Under the $US400 million agreement, Aviron granted Wyeth-Lederle Vaccines exclusive worldwide rights to market FluMist. Wyeth-Lederle Vaccines and Aviron (now Med-Immune Vaccines) will co-promote FluMist in the US, while Wyeth-Lederle Vaccines will have the exclusive right to market the product ex-US. Wyeth will hold marketing rights for up to 11 years. The collaboration excludes Korea, Australia, New Zealand and certain South Pacific countries. The companies will collaborate on the regulatory, clinical and marketing programmes for FluMist and both will manufacture liquid FluMist. MedImmune Vaccines is to receive an average of 40% of revenues from FluMist; the percentage will be higher in the US and lower in other markets. Aviron received a $US15 million upfront payment upon initiation of the agreement. In December 2000, Aviron received a $US15.5 million milestone payment from American Home Products (now Wyeth) after the US FDA accepted the BLA for FluMist. MedImmune Vaccines will receive a $US20 million milestone payment upon US FDA approval. Aviron also received an additional $US20 million in milestone payments for expaory body recommendations. MedImmune Vaccines is entitled to receive a $US10 million payment for submitting a licence application in Europe, a $US27.5 million payment for approval of a refrigerator-stable liquid formulation of FluMist and as much as $US50 million for licensing of FluMist internationally. In July 2003 MedImmune announced that it had received approximately $US28 million in milestone payments during Q2 of 2003 for the approval of FluMist. CSL Ltd of Australia will collaborate on the development, sale and distribution of MedImmune Vaccine's vaccine in Australia, New Zealand and certain countries in the South Pacific. MedImmune is to acquire vaccine research programmes in respiratory syncytial virus and cytomegalovirus from MedImmune Vaccines. The company's primary interest is in FluMist. In May 2002, MedImmune licensed exclusive rights to Crucell's proprietary human cell line PER.C6 for use in its influenza vaccine programmes. On 11 March 2002, American Home Products changed its name and the names of its subsidiaries Wyeth-Ayerst and Wyeth-Lederle to Wyeth. Wyeth's vaccines division is called Wyeth Vaccines. On 29 September 2000, Aviron announced that it had been awarded a $US2.7 million Challenge Grant from NIAID for development of vaccines against pandemic strains of influenza based on FluMist intranasal technology. The cold-adapted live influenza vaccine has been widely evaluated in the US and Japan since 1975 in clinical trials involving several thousand people. Aviron completed phase II clinical trials in adults in the US and phase III trials in US children aged 15-71 months. Additional phase III trials in adults and the elderly are ongoing. Aviron also commenced phase III trials to test the safety of its intranasal live vaccine in children with moderate to severe asthma. The vaccine is delivered using the AccuSpray nasal delivery system by Becton Dickinson, which will supply the system for FluMist through the 2001-2002 influenza season under an agreement with Aviron made in August 1998. On 7 March 2000, Aviron announced that Wyeth-Lederle Vaccines (now Wyeth Vaccines) had begun a phase II bridging study with a refrigerator-stable liquid formulation of FluMist in the Southern Hemisphere. The randomised single-blind trial is being conducted together with Aviron (now MedImmune Vaccines) and is intended to demonstrate clinical equivalence between frozen and liquid FluMist. At the time of the announcement, more than 500 children aged 1-3 years had been enrolled to receive either frozen or liquid FluMist. The final study population is approximately 1300. If clinical equivalence of the two forms of FluMist is demonstrated in this study, MedImmune Vaccines will be able to use data from trials of frozen FluMist in licence applications for international markets. Aviron submitted a Biologics Licence Application (BLA) to the US FDA in July 1998. The FDA rejected this application on the grounds of a lack of data on manufacturing, validation and stability. In June 1999, Aviron announced that it had completed a bridging study on FluMist designed to provide some of the manufacturing data required by the US FDA on FluMist prepared at one of two manufacturing sites. Preliminary analysis indicated that the results had met the company's objectives. The primary endpoint of the study was to demonstrate that the batch of FluMist blended and filled at Packaging Coordinators, Inc. in Philadelphia had similar immunogenicity for all three 1997-98 influenza strains as the vaccine used in earlier clinical trials, which was manufactured by Medeva Pharma (now Evans Vaccines, a subsidiary of PowderJect Pharmaceuticals) in England. The secondary endpoint was to show that these lots of FluMist had similar safety and tolerability profiles. Aviron then submitted a BLA in October 2000. However, in late July 2001, an FDA advisory committee declined to recommend approval of the vaccine, citing concerns with safety. Aviron subsequently received a Complete Response Letter from the FDA requesting additional clinical and manufacturing data. Aviron stated that it should be able to provide these data without conducting further clinical trials. In January 2002, Aviron submitted additional clinical and manufacturing data on FluMist to the US FDA. MedImmune received a second Complete Response Letter from the US FDA on 10 July 2002, requesting clarification and additional data relating to previously submitted information. One of the most significant issues raised by the US FDA was the exacerbated rate of asthma and wheezing in 18-35-month-old patients using FluMist. MedImmune is considering two options to address this issue; to either exclude patients with asthma and wheezing from the label, or to exclude 18- to 30-month-old patients from the proposed indication. On 26 August 2002, MedImmune reported that it had completed the submission of information requested by the US FDA for FluMist. On 17 December 2002, the US FDA's Vaccination and Related Biologicals Products Advisory Committee (VRBPAC) recommended that the FDA approve FluMist to prevent influenza in healthy children, adolescents and adults (ages 5-49 years). Even though the VRBPAC voted in favour of the product's safety in the 50- to 64-year age group, they believed that the data set on efficacy for this age group was insufficient. The committee has also recommended that head-to-head studies should be conducted comparing FluMist to the marketed trivalent inactivated vaccine. Additional clinical trials suggested by the VRBPAC were shedding studies to more clearly define the probability of transmitting the influenza vaccine virus to a high-risk patient and annual revaccination studies. On 30 January 2003, MedImmune announced that it had received a Complete Response Letter from the US FDA requesting clarification and additional information relating to data previously submitted. No additional clinical trials were requested. The company responded to the five questions contained in the letter on 7 February 2003. (ABSTRACT TRUNCATED)

Potent, long lasting systemic antibody levels and mixed Th1/Th2 immune response after nasal immunization with malaria antigen loaded PLGA microparticles

The immunogenicity of the synthetic malaria vaccine SPf66 has been recently improved by the application of new adjuvants as QS-21 saponin or poly-D,L-lactide-co-glycolide (PLGA) polymers. The search for less invasive administration routes made us test the immunogenicity of SPf66-loaded microparticles by the nasal route in Balb/c mice. We report here that the intranasal administration of the adequate PLGA vaccine formulations greatly improves and maintains higher antibody levels compared to the conventional alum adjuvant and to the administration of the particles by other routes (subcutaneous, oral). Systemic immune responses were characterized as mixed Th1/Th2-type: IFN-gamma and IgG2a isotype were found as signs of Th1 activation, whilst IgE and IgG1 secretions indicate Th2 response. Since both types of response have been associated to protective immunity in malaria, we postulate that this new approach supposes an advantage over the traditional adjuvants and routes.

Safety and efficacy of trivalent inactivated influenza vaccine in young children: a summary for the new era of routine vaccination

Increasing use of influenza vaccine in children is expected as this important virus becomes more widely recognized as a major cause of morbidity in young children. Clinicians and third party payers must consider the implications of national vaccine use recommendations, with their current focus on young children, on their practices and on the community at large. Two influenza vaccines are available in the United States, an inactivated, trivalent intramuscular formulation (TIV) which is approved for use among children > or =6 months of age; and a live, attenuated intranasal trivalent preparation (LAIV) indicated for healthy persons 5 to 49 years of age. This review summarizes available data regarding the safety and efficacy of TIV, in comparison with LAIV, with particular attention to children <9 years of age, the population for whom two doses of vaccine are recommended for first time vaccination. It is apparent that relatively few data are available on the safety of TIV in young children, that important age-specific differences in TIV vaccine efficacy exist and that LAIV appears similar to TIV with regard to safety and efficacy in younger children, but no head-to-head comparison of these two licensed products is available.

Safety and efficacy of live attenuated, cold-adapted, influenza vaccine-trivalent

This article describes the efficacy, immunogenicity, and safety of CAIV-T. This vaccine has the potential to significantly contribute to the control of influenza infection and influenza-associated illnesses, including febrile otitis media and lower respiratory disease. When compared with inactivated vaccine, CAIV-T has significant advantages in convenience of administration. The high efficacy of CAIV-T and its efficacy in children against a significantly drifted strain of H3N2 (A/Sydney), a strain not contained in the vaccine, are compelling observations for use of the vaccine in children. Effectiveness in adults was demonstrated using the same vaccine strain against the drifted H3N2 strain. The proposed vaccine administration schedule for healthy individuals aged 9 to 49 years is a single dose administered annually before the winter. For children aged 5 to 8 years, two doses are recommended the first year they are immunized with CAIV-T to ensure protection against all strains contained in the vaccine. Thereafter, a single annual revaccination is sufficient.

Are we ready for universal influenza vaccination in paediatrics?

Recent studies have suggested that paediatric influenza is a greater medical problem than usually thought because it can cause excess hospitalisations, medical visits, and antibiotic prescriptions even in healthy children, especially those under 2 years. Furthermore, influenza in otherwise healthy children may have substantial socioeconomic consequences for the children and their household contacts. These findings have led many experts to encourage the more widespread use of influenza vaccine in childhood. Although the immunogenicity of the available vaccines is good and they are safe, well-tolerated, and highly effective in preventing influenza and its complications, economic data support universal vaccination only when indirect effectiveness is considered. However, infants aged 6-23 months, children with recurrent acute otitis media or respiratory-tract infections, and healthy children attending day-care centres or elementary schools should be included among the paediatric groups requiring vaccination.

Influenza virus: immunity and vaccination strategies. Comparison of the immune response to inactivated and live, attenuated influenza vaccines

Influenza virus is a globally important respiratory pathogen which causes a high degree of morbidity and mortality annually. The virus is continuously undergoing antigenic change and thus bypasses the host's acquired immunity to influenza. Despite the improvement in antiviral therapy during the last decade, vaccination is still the most effective method of prophylaxis. Vaccination induces a good degree of protection (60-90% efficacy) and is well tolerated by the recipient. For those at risk of complications from influenza, annual vaccination is recommended due to the antigenic changes in circulating strains. However, there is still room for improvement in vaccine efficacy, long-lasting effect, ease of administration and compliance rates. The mucosal tissues of the respiratory tract are the main portal entry of influenza, and the mucosal immune system provides the first line of defence against infection. Secretory immunoglobulin A (SIgA) and IgM are the major neutralizing antibodies directed against mucosal pathogens. These antibodies work to prevent pathogen entry and can function intracellularly to inhibit replication of virus. This review describes influenza virus infection, epidemiology, clinical presentation and immune system response, particularly as it pertains to mucosal immunity and vaccine use. Specifically, this review provides an update of the current status on influenza vaccination and concentrates on the two main types of influenza vaccines currently in use, namely the cold-adapted vaccine (CAV) given intranasally/orally, and the inactivated vaccine (IV) delivered subcutanously or intramuscularly. The commercially available trivalent IV (TIV) elicits good serum antibody responses but induces poorly mucosal IgA antibody and cell-mediated immunity. In contrast, the CAV may elicit a long-lasting, broader immune (humoral and cellular) response, which more closely resembles natural immunity. The immune response induced by these two vaccines will be compared in this review.

Mucosal immunity: overcoming the barrier for induction of proximal responses

Vaccination represents one of the most efficacious and cost-effective medical interventions. It is the only medical intervention proven to eliminate disease at a global level. Many of the pathogens against which we most require adequate vaccines infect via the highly exposed mucosal surfaces. For this reason the mucosa is often considered the first, and sometimes only, line of defense. Therefore, responses that protect the local mucosa are vital. In this review, we first explore the immunological mechanisms that protect the mucosa. We then review the literature of mucosal vaccines within the principles of antigenic composition, dose, and danger, highlighting the need and niche for the next generation of mucosal vaccines.

Every nose counts: a new influenza vaccine for all healthy schoolchildren?

Influenza is a vaccine-preventable disease. However, influenza virus spreads among children in schools and daycare centers, then to families and communities, causing uncontrolled epidemics every winter. The United States Food and Drug Administration evaluated and approved an investigational live-attenuated, cold-adapted, trivalent influenza vaccine for licensure, for prevention of influenza in healthy children and healthy adults, 5 through 49 years of age. Could protection of healthy schoolchildren against influenza limit its spread and benefit society?

Intranasal cold-adapted influenza virus vaccine combined with inactivated influenza virus vaccines: an extra boost for the elderly?

Although influenza vaccine delivery strategies have improved coverage rates to unprecedented levels nationally among persons aged 65 years and older, influenza remains one of the greatest vaccine-preventable threats to public health among elderly in the US. A new, intranasal live attenuated influenza vaccine (LAIV) was recently approved by the US FDA for use in persons aged 5-49 years, which excludes the elderly population. Limitations of immune response to inactivated influenza vaccine (IAIV) and effectiveness of current influenza vaccination strategies among the elderly suggest that a combined approach using LAIV and/or the IAIV in various permutations might benefit this group. We explore characteristics of the LAIV, data regarding its utility in protecting against influenza in the elderly, and challenges and opportunities regarding potential combined inactivated/live attenuated vaccination strategies for the elderly. Although LAIV appears to hold promise either alone or in combination with IAIV, large well conducted randomised trials are necessary to define further the role of LAIV in preventing influenza morbidity and mortality among the elderly. We also suggest that innovative vaccine coverage strategies designed to optimise prevention and control of influenza and minimise viral transmission in the community must accompany, in parallel, the acquisition of clinical trials data to best combat morbidity and mortality from influenza.

A nasal Proteosome influenza vaccine containing baculovirus-derived hemagglutinin induces protective mucosal and systemic immunity

The potential for enhancing the immunogenicity of recombinant (baculovirus-derived) influenza hemagglutinin (rHA) was investigated by comparing the immune responses elicited in mice by an intranasal (i.n.) rHA formulated with Proteosomes, with those induced by intramuscular (i.m.) or i.n. rHA alone. The Proteosome-rHA vaccine induced mucosal responses in the respiratory tract, as well as high serum IgG and hemagglutination inhibition (HAI) titers. In contrast, rHA alone given i.m. induced serum IgG without mucosal responses and was ineffective at inducing either mucosal or systemic responses when given i.n. Only mice immunized with the Proteosome-rHA vaccine were completely protected from both death and acute morbidity following live virus challenge, indicating that the i.n. Proteosome-rHA vaccine induced more complete protective immunity than the same doses of unformulated rHA given i.n. or i.m.

Upper Respiratory Tract Immunity

Most viral infections occur via mucosal surfaces like the respiratory, gastrointestinal, or genital epithelium. The mucosal immune system is an important component of the body's defense against such infections and consequently induction of mucosal, in addition to systemic immunity, might improve vaccine efficacy. Several orally administered vaccines, for example, against poliovirus and gastrointestinal bacterial infections, have been developed and are widely used. In contrast, to date most vaccines against respiratory pathogens are applied parenterally and thus do not induce significant mucosal immunity. For the development of effective mucosal vaccines a more profound understanding of the immune mechanisms operative at mucosal surfaces and of the interplay between different mucosal compartments is needed. Moreover, factors like the dose, form of application, and type of mucosal adjuvants are critical to the induction of effective mucosal immunity. This brief review will focus mainly on the nasal route and will summarize some recent findings concerning the function of the mucosal immune system of the upper respiratory tract. Furthermore, routes of cross-immunization between distinct mucosal compartments and how they might be relevant to vaccine development will be addressed. Finally, I will outline critical factors for the rational design of nasal vaccines and in this context highlight some recent preclinical and clinical developments in the field.

Route of administration is the prime determinant of IgA and IgG2a responses in the respiratory tract of mice to the cold-adapted live attenuated influenza A donor strain A/Leningrad/134/17/57

Serum antibody and antibody secretory cell (ASC) responses to the cold-adapted (CA) live attenuated influenza A donor strain A/Leningrad/134/17/57 in BALB/c mice were determined in the lungs and mediastinal lymph nodes after administration by the intranasal, subcutaneous and intramuscular routes. Both types of response were greatest when an inoculum consisting of 10(6.5) 50% egg infectious doses (EID(50)) was administered twice intranasally at an interval of 3 weeks. Serum responses by the intramuscular route were much higher than by the subcutaneous route but, at doses of 10(6.5-7.5) EID(50), were still lower than that obtained with two doses of an intranasal inoculum of 10(6.5) EID(50). Virus-specific ASC responses for IgA and IgG2a were obtained in the lungs and mediastinal lymph nodes of mice inoculated with 10(6.5) EID(50) by the intranasal route. However, ASC responses after inoculation by either the subcutaneous or intramuscular routes were barely detectable, even at doses as high as 10(7.5) EID(50). These results confirm that intranasal administration of live vaccines induces far higher virus-specific IgA and IgG2a responses in the respiratory tract of mice than can be achieved by parenteral administration and that serum antibody levels induced by parenteral vaccination are unrelated to the respiratory ASC response.

Epidermal powder immunization of mice and monkeys with an influenza vaccine

Epidermal powder immunization (EPI) with an influenza vaccine and an adjuvant such as QS-21, LTR72, or cholera toxin elicited augmented serum and mucosal antibody responses in mice. Rhesus macaques, which have an immune system and skin structure similar to humans, were used to further evaluate the immunogenicity of the influenza vaccine following EPI. EPI of rhesus macaques with an influenza vaccine and QS-21 adjuvant elicited significantly higher serum hemagglutination inhibition (HI) titers than antigen alone administered by EPI or by intramuscular (IM) injection using a needle and syringe. In the absence of QS-21, EPI and IM injection elicited comparable HI titers in the monkeys. This study suggests that EPI is a promising technique for administering human vaccine and that QS-21 augments the immunogenicity of co-administered influenza vaccine.

The Etiology, Pathophysiology, and Management of Otitis Media with Effusion

Otitis media with effusion (OME) is a common and important condition that may result in developmental delay in children, and significant health care resources are devoted to its management. Newer techniques including polymerase chain reaction are implicating organisms not previously considered important in etiology. The role of gastroesophageal reflux as a cause of OME is likely to receive greater research attention. Regarding prevention, more is being learned about potentially modifiable risk factors such as environmental smoke, care outside the home, and breast feeding. Although immunization may to play a role in the future, existing evidence suggests that the general population of children should not be immunized in order to prevent OME. Several major studies have recently added to the understanding of epidemiology and management. Large trials in the United States, the Netherlands, and the UK suggest that OME is not an appropriate condition to include in a screening program. In addition, the advantages of early treatment with ventilation tubes over watchful waiting in terms of language development tend be modest and diminish by about 18 months. Treatment with hearing aids should be further evaluated. The search for effective medical management continues, and better ways are being identified of targeting interventions to those children with OME who are most likely to benefit.

Safety and immunogenicity of a live-attenuated influenza vaccine blended and filled at two manufacturing facilities

This study was designed to compare the safety and immunogenicity of a trivalent live-attenuated, cold-adapted influenza vaccine (CAIV-T) blended and filled at two different manufacturing facilities (Medeva and Aviron-PA). The vaccines contained approximately 10(7) TCID(50) (median tissue culture infectious dose) of each of the three recommended 1997-1998 influenza vaccine components, A/Shenzhen/227/95 (H1N1) (A/Bayern/7/95 (H1N1)-like strain), A/Wuhan/359/95 (H3N2), and B/Ann Arbor/1/94 (B/Beijing/184/93-like strain). Two hundred and twenty-five healthy Australian children aged 12-42 months were enrolled and randomized in a 3:2 ratio to receive CAIV-T blended and filled either at Medeva or at Aviron-PA. Two doses of CAIV-T were given 4-6 weeks apart as an intranasal spray. Three blood specimens were collected (immediately before doses one and two, and 28 +/- 5 days following dose two) for measuring hemagglutination inhibition (HAI) antibody responses. Adverse events occurring within 10 days and serious adverse events occurring within 42 days were collected. Serum HAI antibody levels were measured against the three vaccine strains. Equivalent immunogenicity between the two vaccine groups was pre-specified as: (1) within 20% difference in seroconversion rates (HAI titers > or =4-fold rise); and (2) within 4-fold difference in the 90% confidence interval of geometric mean titer ratio. Among 10 pre-specified adverse events, only vomiting had significantly different incidence rates in the two vaccine groups following dose one (3% versus 13%, P = 0.01) but the difference disappeared following dose two (4% versus 4%). Differences in seroconversion rates following dose two between the two vaccine groups in pre-vaccination seronegative children were all <20% for the three vaccine strains (16% for H1N1, 0% for H3N2, and 0% for B). The results indicate that CAIV-T blended and filled in the two facilities had equivalent profiles of safety and immunogenicity.

[Influenza]

Influenza (flu) is an acute contagious viral infection characterized by inflammation of the respiratory tract that every winter affects more than 100 million people in Europe, Japan and the United States of America, also being responsible for several thousand of excess deaths (data from the United States reveal between 20,000 to 40,000 excess deaths annually). The Mixovirus influenzae is the agent that causes influenza, commonly called flu. There are 3 types of influenza virus: A, B, C, and only types A and B are perceived to be clinically relevant in humans. Due to the segmented nature of its genetic material, the influenza virus is highly mutagenic, causing frequent insertion of new antigenic strains into the community, against which the population presents no immunity. Presently, there are few options for the control of influenza and annual immunization is the most effective means to prevent disease and its complications. In Brazil, according to data collected by the VigiGripe's Project - linked to the Federal University of Sao Paulo -, circulation of the influenza virus also has a seasonal pattern, with peak activity occurring between May and September. Yearly vaccination is, therefore, best indicated on March and April. Currently, there are four medications available for the treatment of influenza viruses: amantadine and rimantadine, and two second generation pharmaceutical products, the neuraminidase inhibitors, oseltamivir and zanamivir. The latter two drugs have set the stage for a new approach to the management and control of influenza infections.

Effect of yearly vaccinations with live, attenuated, cold-adapted, trivalent, intranasal influenza vaccines on antibody responses in children

BACKGROUND

The cold-adapted, trivalent influenza vaccine (CAIV-T) may become an option for annual vaccination. However, there is little information regarding the immune response to repeated immunization with CAIV-T.

OBJECTIVE

To determine the antibody response to repeated immunization with CAIV-T and to compare this with the response after the first CAIV-T immunization.

DESIGN AND METHODS

Healthy children were offered CAIV-T immunization for 4 consecutive years, and blood samples were taken from a subset in Years 1, 2 and 4. In Year 4, 156 similarly aged children who had not received influenza vaccine previously were immunized with the same CAIV-T.

RESULTS

The H3N2 and B components of the CAIV-T induced high antibody titers in Year 1 that were maintained during 4 years. The H1N1 titers were lower than the H3N2 or B titers. Comparison of the group immunized for 4 consecutive years with the group immunized for the first time revealed the following: (1) before immunization yearly immunized subjects were more likely to be seropositive to each of the three vaccine strains than those immunized for the first time (P < 0.05 for each); (2) after immunization the percentage of seropositive subjects to each of the strains was similar; (3) after immunization titers were higher in the subjects immunized for the first time than those immunized yearly (P < 0.05 for H3N2 and B).

CONCLUSION

Yearly vaccination with CAIV-T induced high antibody titers, especially to the H3N2 and B strains in the vaccines. The titers in those immunized with CAIV-T for the first time were higher than in those immunized for 4 consecutive years.

Technical report: Reduction of the influenza burden in children

Epidemiologic studies have shown that children of all ages with certain chronic conditions, such as asthma, and otherwise healthy children younger than 24 months (6 through 23 months) are hospitalized for influenza and its complications at high rates similar to those experienced by the elderly. Annual influenza immunization is already recommended for all children 6 months and older with high-risk conditions. By contrast, influenza immunization has not been recommended for healthy young children. To protect children against the complications of influenza, increased efforts are needed to identify and recall high-risk children. In addition, immunization of children between 6 through 23 months of age and their close contacts is now encouraged to the extent feasible. Children younger than 6 months may be protected by immunization of their household contacts and out-of-home caregivers. The ultimate goal is universal immunization of children 6 to 24 months of age. Issues that need to be addressed before institution of routine immunization of healthy young children include education of physicians and parents about the morbidity caused by influenza, adequate vaccine supply, and appropriate reimbursement of practitioners for influenza immunization. This report contains a summary of the influenza virus, protective immunity, disease burden in children, diagnosis, vaccines, and antiviral agents.

Safety of the trivalent, cold-adapted influenza vaccine in preschool-aged children

OBJECTIVE

To provide additional information on the safety of trivalent, cold-adapted influenza vaccine (CAIV-T) in children.

METHODS

Children 15 to 71 months of age were enrolled in a multicenter, prospective, randomized, double-blind, and placebo-controlled trial to receive by nasal spray CAIV-T or placebo. In year 1 (1996-1997), 1314 were enrolled in the 2-dose cohort and 288 were enrolled in the 1-dose cohort. In year 2 (1997-1998), 1358 of the original participants received 1 dose of vaccine or placebo according to their original treatment group assignment. In year 3 (1998-1999) and year 4, the trial continued as an open-label safety trial of CAIV-T. A total of 642 and 549 children enrolled in years 3 and 4, respectively, received their third and fourth sequential annual doses of CAIV-T. Measured were 1) the occurrence of specific respiratory, gastrointestinal and systemic symptoms, unexpected symptoms (not specified in the diary card), and use of medications within the first 10 days after vaccination; 2) the occurrence of an acute illness and use of medication within 11 to 42 days after vaccination; and 3) the occurrence of serious adverse events within 42 days after vaccination.

RESULTS

The adjusted odd ratios of specific respiratory and gastrointestinal symptoms during the 10 days after vaccination were determined in years 1 and 2. Runny nose or nasal congestion, vomiting, muscle aches, and fever were significantly associated with the first dose of CAIV-T. With the second dose, runny nose was the only symptom that was associated with CAIV-T. In year 2, CAIV-T did not cause excess in any of the specific respiratory and gastrointestinal symptoms. In years 3 and 4, specific respiratory and gastrointestinal symptoms were comparable to that observed in year 2. A CAIV-T-associated symptom was most likely to occur on day 2 with the first dose of vaccine. The occurrence of unexpected symptoms was primarily of the gastrointestinal system. Approximately 6% of CAIV-T and 3.6% of placebo recipients had a gastrointestinal symptom. CAIV-T seemed to be associated with a mild excess in abdominal pain and vomiting only with the first vaccine dose. A statistically significant increase in the use of analgesics/antipyretics was detected only with the first dose in CAIV-T vaccinees compared with placebo recipients (23.5% vs 16.6%). Between days 11 and 42, CAIV-T use was not associated with an excess of illness, otitis media, or use of medication. None of the 6 serious adverse events in CAIV-T recipients in years 1 to 4 was attributed to the vaccine.

CONCLUSIONS

CAIV-T was safe in children. Mild respiratory, gastrointestinal, and systemic symptoms of short duration were observed in a minority of children and primarily with the first vaccine dose. Sequential annual doses of CAIV-T were well tolerated.

Influenza vaccines in children

Influenza is a common disease of childhood. Young children and children with high-risk medical conditions are at increased risk of being hospitalized when infected with influenza virus. Children of all ages have excess physician visits and receive excess antibiotic prescriptions during influenza season. The safety, immunogenicity, and efficacy of influenza vaccines in children are described in this review. Clinical trials and postlicensure experience have demonstrated that trivalent inactivated influenza vaccine is well-tolerated in children. Efficacy of the inactivated vaccine also has been demonstrated in numerous clinical trials. In comparison to trivalent inactivated influenza vaccine, investigational cold-adapted, live-attenuated influenza vaccine (LAIV) has the advantage of an intranasal route of administration. A large clinical trial demonstrated the tolerability and efficacy of the trivalent live, attenuated product in children 15 to 71 months of age. Pending information on safety and coadministration of this vaccine with other childhood vaccines will determine if it is licensed and recommended for use in children, including possible expanded indications for routine yearly administration to young children.

Universal vaccination of healthy children against influenza: a role for the cold-adapted intranasal influenza vaccine

The incidence of influenza in children well exceeds that of the elderly and has been identified as the basis for 20% of doctor visits for children during the winter. The disease results in over 100 hospitalizations per 100000 person-months in children <2 years of age. Furthermore, children serve as the major vector in the community; thus, influenza in children results in significant costs to society. Although efficacious, the current intramuscular, inactivated influenza vaccine is infrequently used in children, and is currently targeted only at children at high risk and those who are household members of such individuals. Experts believe that vaccinating only high risk individuals has little impact on the cycle of annual epidemics, but that universal vaccination of children may very well have a substantial impact. Experimental data support this. A recently published cost-benefit analysis indicated that routine, school-aged vaccination through individual visits to a clinician would save 4 US dollars per child vaccinated. A group program such as a school-based one would save 35 US dollars. One obstacle to universal vaccination includes the real and perceived resistance to the addition of yet another annual injection to the already crowded schedule of routine childhood immunizations. Nearing licensure is an intranasal, live attenuated, cold-adapted intranasal influenza vaccine. Cold-adaptation prevents replication in the lower respiratory tract. Trials have demonstrated immunogenicity, safety, and tolerability in adults as well as children. Placebo-controlled trials have shown efficacy rates of 83 to 94%. This novel vaccine addresses obstacles to universal childhood immunization and would permit a program of routine use that would dramatically reduce transmission and stem epidemics of influenza.

Intranasal immunization with recombinant antigens associated with new cationic particles induces strong mucosal as well as systemic antibody and CTL responses

New cationic nanoparticles (SMBV) were evaluated for use as a nasal vaccine delivery system for two recombinant proteins: HBsAg and beta-galactosidase. Each protein was formulated with SMBV and intranasally administrated to non-anesthetized mice. In each model, the formulated protein induced high levels of specific serum IgG antibodies and cytotoxic T lymphocyte (CTL) responses. Moreover, specific IgA antibodies were found in nasal as well as in vaginal washes of intranasally immunized mice with the protein associated with SMBV. In contrast, no IgG or IgA antibodies and no CTL were detected in mice immunized with free protein. The detection of a CTL response and an increase in both IgG1 and IgG2a antibodies in serum suggest that SMBV amplifies both Th1 and Th2 responses without modifying the Th1/Th2 profile of the immune response induced by the natural protein. These data demonstrate the high potential of SMBV for use as a nasal delivery system for sub-unit vaccines.

Epidermal powder immunization using non-toxic bacterial enterotoxin adjuvants with influenza vaccine augments protective immunity

The non-toxic B subunit of cholera toxin (CTB) and E. coli heat-labile toxin mutant proteins with reduced toxicity (LTR72) or no toxicity (LTK63) were used as adjuvants for epidermal powder immunization (EPI) with an influenza vaccine. When administered by EPI, CTB, LTR72 and LTK63 significantly augmented antibody responses to the influenza vaccine and protection against a lethal challenge in a mouse model. The antigen dose could be reduced by 125-fold. These adjuvants were well-tolerated both locally and systemically following EPI. These results suggest that EPI with influenza vaccine and a non-toxic bacterial enterotoxin hold promise for human vaccination.

Cold-adapted influenza vaccines

Because of the health impact of complicated disease from influenza in children, the role played by children in spreading influenza, and the limitations of inactivated influenza vaccine in this population, there has been ongoing effort to identify a more effective and acceptable vaccine. This review will focus on the development, limitations, and potential of a leading candidate vaccine studied in children. This is a live, attenuated, intranasally administered cold-adapted influenza vaccine.

An open-label comparison of the immunogenicity and tolerability of intranasal and intramuscular formulations of virosomal influenza vaccine in healthy adults

BACKGROUND

Many intramuscular inactivated influenza vaccines achieve suboptimal results in the prevention of respiratory disease and influenza complications. This has led to the current interest in developing effective oral or intranasal preparations.

OBJECTIVE

This study compared the immunogenicity and tolerability of intranasal and intramuscular formulations of virosomal subunit influenza vaccine in healthy adults. It also assessed the immunogenicity and tolerability of 3 different production lots of the intranasal vaccine containing Escherichia coli heat-labile toxin adjuvant.

METHODS

This was a multicenter, Phase I, randomized, open-label pilot study in which the primary end point was immunogenicity (hemagglutination-inhibition [HI] antibody assay on days 1 and 29). The secondary end point was the frequency of adverse events (AEs). Subjects were assigned to 4 vaccination groups: groups AI, AII, and AIII received intranasal influenza vaccine from batches that differed in the hemagglutinin and neuraminidase strains used, and group B received intramuscular virosomal subunit vaccine. Assessments of health status, hematology, biochemistry, body temperature, heart rate, blood pressure, and incidence of AEs were made on days 1, 8, and 29, and serology was assessed on days 1 and 29.

RESULTS

The study enrolled 88 subjects. All 3 production lots of intranasal vaccine induced an immune response to most of the viral strains administered (A/Singapore, A/Texas, A/Wuhan, B/Beijing), with no notable immunogenic differences between lots. After intranasal vaccination, geometric mean titers (GMT) increased 2.7-fold against A/Singapore (group AI); 1.8- and 3.1-fold against A/Texas (groups AII and AIII, respectively); 1.9- to 2.4-fold against A/Wuhan; and 1.5- to 1.7-fold against B/Beijing. After intramuscular vaccination. GMT increased 11.3-, 6.3-, and 2.7-fold against A/Texas, A/Wuhan, and B/Beijing, respectively. Seroprotection (HI antibody titers > or = 1:40 in > 70% of those vaccinated) was achieved against all strains in the group that received intramuscular vaccination, against A/Wuhan in all groups that received intranasal vaccination, and against A/Texas in group AII. Both vaccine formulations were well tolerated. Intranasal vaccination was associated with a low incidence ( < 20%) of nasal AEs.

CONCLUSIONS

Both the intranasal and intramuscular vaccinations elicited a systemic immune response and were well tolerated. The different batches of intranasal vaccine showed a similar immunogenic profile. Intranasal administration may be preferred to intramuscular administration by some patients.

Safety, efficacy and effectiveness of cold-adapted, live, attenuated, trivalent, intranasal influenza vaccine in adults and children

Studies in children and adults revealed cold-adapted, live, attenuated, trivalent, intranasal influenza vaccine (CAIV-T) to be well accepted, well tolerated and highly protective against culture-confirmed influenza, and to provide significant health benefits. A 2 year, multicentre, double-blind, placebo-controlled efficacy field trial of CAIV-T in children aged 15-71 months with annual re-immunization revealed the vaccine to be highly protective against culture-confirmed influenza. Vaccine induced serum and secretory antibodies in vaccinated children. Overall, during 2 years of study, vaccine was 92% protective against culture-confirmed influenza. During the second year of study the vaccine was 86% protective against influenza A/Sydney/5/97-like virus, a significantly drifted strain not well matched to the vaccine. Antibody studies on children given CAIV-T revealed that high titres of cross-reacting antibodies to influenza A/Sydney/5/97 were induced with vaccination by live attenuated influenza A/Wuhan/359/95-like vaccine. Effectiveness measures revealed significant reductions in febrile illness (21% reduction in year 1, 19% reduction in year 2), febrile otitis media (33% reduction in year 1, 16% reduction in year 2) and associated antibiotic use among vaccinated children compared with placebo recipients. In adults, vaccination with CAIV-T resulted in protection during experimental challenge with virulent wild-type viruses. An effectiveness trial in adults demonstrated significant benefits of CAIV-T vaccine (28% reduction in days of missed work for febrile upper respiratory illness days with associated 45% reduction in days taking antibiotics). General use of CAIV-T has the potential to significantly reduce the impact of influenza in children and adults.

Plasmid-only rescue of influenza A virus vaccine candidates

The potential threat of another influenza virus pandemic stimulates discussion on how to prepare for such an event. The most reasonable prophylactic approach appears to be the use of effective vaccines. Since influenza and other negative-stranded RNA viruses are amenable to genetic manipulation using transfection by plasmids, it is possible to outline new reverse genetics-based approaches for vaccination against influenza viruses. We suggest three approaches. First, we use a plasmid-only rescue system that allows the rapid generation of high-yield recombinant vaccine strains. Second, we propose developing second-generation live influenza virus vaccines by constructing an attenuated master strain with deletions in the NS1 protein, which acts as an interferon antagonist. Third, we suggest the use of Newcastle disease virus recombinants expressing influenza virus haemagglutinin proteins of pandemic (epizootic) strains as novel vaccine vectors for use in animals and possibly humans.