Cold-adapted recombinant influenza A virus vaccines in seronegative young children

A Mutated PB1 Residue 319 Synergizes with the PB2 N265S Mutation of the Live Attenuated Influenza Vaccine to Convey Temperature Sensitivity

Current influenza vaccines have modest efficacy. This is especially true for current live attenuated influenza vaccines (LAIV), which have been inferior to the inactivated versions in recent years. Therefore, a new generation of live vaccines may be needed. We previously showed that a mutation at PB1 residue 319 confers enhanced temperature sensitivity and attenuation in an LAIV constructed in the genetic background of the mouse-adapted Influenza A Virus (IAV) strain A/PR/8/34 (PR8). Here, we describe the origin/discovery of this unique mutation and demonstrate that, when combined with the PB2 N265S mutation of LAIV, it conveys an even greater level of temperature sensitivity and attenuation on PR8 than the complete set of attenuating mutations from LAIV. Furthermore, we show that the combined PB1 L319Q and PB2 N265S mutations confer temperature sensitivity on IAV polymerase activity in two different genetic backgrounds, PR8 and A/Cal/04/09. Collectively, these findings show that the PB2 LAIV mutation synergizes with a mutation in PB1 and may have potential utility for improving LAIVs.

Live Attenuated Influenza Vaccine: Is Past Performance a Guarantee of Future Results?

Live attenuated influenza vaccine (LAIV) has had a tumultuous recent history that can be difficult for many to follow and understand. Prior to 2013, LAIV had a record of accomplishment of providing equal or superior protection against influenza in children. Since 2013, concerns about the lack of protection with LAIV against pandemic H1N1 strains led to the withdrawal of any recommendation for use in the US by the Advisory Committee on Immunization Practices (ACIP). After some significant changes to the content, evaluation and production of LAIV, it has been be recommended again for use in the US in 2018-19. This commentary reviews the origin of LAIV, the events and circumstances that led to the withdrawal of any recommendation for LAIV use by the ACIP, the merits, shortcomings and repercussions of that decision and finally offers some thoughts about the future of LAIV.

Duration of Virus Shedding After Trivalent Intranasal Live Attenuated Influenza Vaccination in Adults

Objective:

To characterize the probability and duration of viral shedding among adults given trivalent live attenuated influenza vaccine (LATV).

Design:

Prospective surveillance study.

Methods:

Nasal wash samples were collected from adult volunteers at baseline and on days 3, 7, and 10 and between days 17 and 21 following intranasal LAIV vaccination. The presence, titer, and identification of each specific strain of influenza virus shed were determined by standard methodology.

Results:

Twenty subjects received LATV. No samples were positive for influenza virus at baseline. After LAIV vaccination, influenza virus was recovered from 10 of 20 vaccinees on day 3, from 1 of 18 vaccinees on day 7, and from none of the samples on days 10 or 17 through 21. Vaccinees who shed vaccine virus were significantly younger than those who did not (mean age, 26.4 vs 38.6 years;P< .01). Although the presence of specific mucosal immunoglobulin A to influenza B was associated with significantly less shedding of influenza B after vaccination (P= .02), associations of shedding with other measures of immunity were not detected.

Conclusion:

The duration of shedding of vaccine virus after LAIV in adults is limited and may be associated with an individual's prior influenza vaccination history.

Randomized comparative study of the serum antihemagglutinin and antineuraminidase antibody responses to six licensed trivalent influenza vaccines

BACKGROUND

Serum antibody to the hemagglutinin (HA) surface protein of influenza virus induced by influenza vaccination is a correlate of protection against influenza. The neuraminidase (NA) protein is also on the surface of the virus; antibody to it has been shown to impair virus release from infected cells and to reduce the intensity of influenza infections in animal models and in humans challenged with infectious virus. Recently we have shown that NA inhibiting antibody can independently contribute to immunity to naturally-occurring influenza immunity in the presence of antibody to the HA.

PURPOSE

The present study was conducted to evaluate induction of antibody to the NA and the HA by commercially available influenza vaccines.

METHODS

Healthy young adults were vaccinated with one of five commercially available trivalent inactivated vaccines or live influenza vaccine. Frequencies of serum antibody and fold geometric mean titer (GMT) increases four weeks later were measured to each of the three vaccine viruses (A/H1N1, A/H3N2, B) in hemagglutination-inhibition (HAI) and neutralization (neut) assays. Frequency and fold GMT increase in neuraminidase-inhibition (NI) antibody titers were measured to the influenza A viruses (A/H1N1, A/H3N2).

RESULTS

No significant reactogenicity occurred among the vaccinated subjects. The Fluvirin inactivated vaccine induced more anti-HA antibody responses and a higher fold GMT increase than the other inactivated vaccines but there were no major differences in response frequencies or fold GMT increase among the inactivated vaccines. Both the frequency of antibody increase and fold GMT increase were significantly lower for live vaccine than for any inactivated vaccine in HAI and neut assays for all three vaccine viruses. Afluria inactivated vaccine induced more N1 antibody and Fluarix induced more N2 antibody than the other vaccines but all inactivated vaccines induced serum NI antibody. The live vaccine failed to elicit any NI responses for the N2 NA of A/H3N2 virus and frequencies were low for the N1 of A/H1N1 virus.

CONCLUSIONS

Trivalent inactivated influenza vaccines with similar HA dosage induce similar serum anti-HA antibody responses in healthy adults. Current inactivated vaccines all induce serum anti-NA antibody to the N1 and N2 NA proteins but some are better than others for N1 or N2. The live vaccine, Flumist, was a poor inducer of either anti-HA or anti-NA serum antibody compared to inactivated vaccine in the healthy adults. In view of the capacity for contributing to immunity to influenza in humans, developing guidelines for NA content and induction of NA antibody is desirable.

Intranasal administration of influenza vaccines: current status

AbstractThis review article focuses on intranasal immunisation against influenza,although it also encompasses antigen uptake and processing in the nasopharyngealpassages, host defence from influenza and current influenza vaccination practices.Improvement of current vaccination strategies is clearly required; current proceduresinvolve repeated annual injections that sometimes fail to protect the recipient. It isenvisaged that nonpercutaneous immunisation would be more attractive to potentialvaccinees, thus improving uptake and coverage. As well as satisfying noninvasivecriteria, intranasal influenza immunisation has a number of perceived immunologicaladvantages over current procedures. Perhaps one of the greatest attributes of thisapproach is its potential to evoke the secretion of haemagglutinin-specific IgAantibodies in the upper respiratory tract, the main site of viral infection. Inactivated influenza vaccines have the advantage that they have a long historyof good tolerability as injected immunogens, and in this respect are possibly morelikely to be licensed than attenuated viruses. Inert influenza vaccines are poormucosal immunogens, requiring several administrations, or prior immunologicalpriming, in order to engender significant antibody responses. The use of vaccinedelivery systems or mucosal adjuvants serves to appreciably improve theimmunogenicity of mucosally applied inactivated influenza vaccines. As is the casewhen they are introduced parenterally, inactivated influenza vaccines are relativelypoor stimulators of virus-specific cytotoxic T lymphocyte activity following nasalinoculation. Live attenuated intranasal influenza vaccines are at a far moreadvanced stage of clinical readiness (phase III versus phase I). With the use of liveattenuated vaccines, it is possible to stimulate mucosal and cell-mediatedimmunological responses of a similar kind to those elicited by natural influenzainfection. In children, recombinant live attenuated cold-adapted influenza viruses arewell tolerated. Moreover, cold-adapted influenza viruses usually stimulate protectiveimmunity following only a single nasal inoculation. Safety of recombinant liveattenuated cold-adapted influenza viruses has also been demonstrated in high riskindividuals with cystic fibrosis, asthma, cardiovascular disease and diabetes mellitus.They are not suitable for immunising immunocompromised patients, however, andare poorly efficacious in individuals with pre-existing immunity to strains closelyantigenically matched with the recombinant virus. According to the reviewedliterature, it is apparent that intranasal administration of vaccine as an aerosol issuperior to administration as nose drops. The information reviewed in this papersuggests that nasally administered influenza vaccines could make a substantialimpact on the human and economic cost of influenza.

Influenza vaccines have a short but illustrious history

Isolation of the causative virus of influenza in 1933, followed by the discovery of embryonated hen eggs as a substrate, quickly led to the formulation of vaccines. Virus-containing allantoic fluid was inactivated with formalin. The phenomenon of antigenic drift of the virus HA was soon recognized and, as WHO began to coordinate the world influenza surveillance, it became easier for manufacturers to select an up-to-date virus. Influenza vaccines remain unique in that the virus strain composition is reviewed yearly but modern attempts are being made to free manufacturers from this yolk by investigating internal virus proteins including M2e and NP as “universal” vaccines covering all virus sub types. Recent technical innovations have been the use of Vero and MDCK cells as the virus cell substrate, the testing of two new adjuvants and the exploration of new presentations to the nose or epidermal layers as DNA or antigen mixtures. The international investment into public health measures for a global human outbreak of avian H5N1 influenza is leading to enhanced production of conventional vaccine and to a new research searchlight on T cell epitope vaccines, viral live attenuated carriers of influenza proteins and even more innovative substrates to cultivate virus, including plant cells.

A randomized, double-blind study of the safety, transmissibility and phenotypic and genotypic stability of cold-adapted influenza virus vaccine

BACKGROUND

Live attenuated influenza vaccine (LAIV; FluMist) is a trivalent vaccine containing cold-adapted influenza vaccine viruses that infect and replicate in cells lining the nasopharynx to induce immunity. Recovery of viruses (shedding) is measured by culture of nasal specimens. Shedding of vaccine viruses is not equated with transmission because transmission requires more virus than is detected in many nasal swabs. Previous studies with LAIV did not detect transmission to close contacts. The primary objective of this study was to estimate the probability of transmission to placebo contacts in a day care setting.

METHODS

One hundred ninety-seven healthy children aged 9 to 36 months attending day care were randomized to receive vaccine or placebo. Postvaccination viral shedding, safety, genotype and phenotype of shed viruses and probability of transmission were assessed.

RESULTS

Eighty percent of 98 vaccine recipients shed at least one vaccine strain. No clinically significant differences in solicited adverse events attributable to vaccine occurred; safety profiles were similar in both groups. Vaccine virus isolates retained their phenotypic characteristics (cold adaptation and temperature sensitivity) and did not revert at nucleotides known to confer an attenuating phenotype. There was one confirmed transmission of a vaccine strain to a single placebo recipient. According to the Reed-Frost model, the calculated probability of transmission to a child after contact with a single vaccinated child was 0.58% (95% confidence interval, 0-1.7%). There was no increased reactogenicity or other safety concerns in the recipient child.

CONCLUSIONS

Young children in a day care setting had a high rate of shedding and a low rate of transmission. No clinically significant illness occurred among children who received vaccine or placebo or in the child to whom the vaccine virus was transmitted.

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.

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.

Intranasal Cold-Adapted Influenza Virus Vaccine Combined with Inactivated Influenza Virus Vaccines

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.

An update on the prevention of influenza in children and adolescents

Influenza virus types A and B cause yearly outbreaks of respiratory tract infections in all age groups including children and adolescents. Complications, such as high fever, febrile convulsions, secondary bacterial infections and myositis frequently lead to hospitalisation. Safe and effective split, subunit and virosome vaccines are available from 6 months of age onwards. Most European countries do have guidelines for the use of influenza vaccines and current strategies primarily aim at decreasing the burden of influenza disease in certain, heterogeneously defined high risk groups.

CONCLUSION

unfortunately, compliance of many physicians and patients with immunisation recommendations is rather poor and several barriers to immunisation have been identified. These deserve our specific attention in the future. Recently, neuraminidase inhibitors with curative and preventive efficacy against influenza virus types A and B have become available. They serve as second line weapons for influenza prophylaxis under specific circumstances.

The NB protein of influenza B virus is not necessary for virus replication in vitro

The NB protein of influenza B virus is thought to function as an ion channel and therefore would be expected to have an essential function in viral replication. Because direct evidence for its absolute requirement in the viral life cycle is lacking, we generated NB knockout viruses by reverse genetics and tested their growth properties both in vitro and in vivo. Mutants not expressing NB replicated as efficiently as the wild-type virus in cell culture, whereas in mice they showed restricted growth compared with findings for the wild-type virus. Thus, the NB protein is not essential for influenza B virus replication in cell culture but promotes efficient growth in mice.

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.

The role of live influenza vaccines in children

Live attenuated cold-adapted influenza vaccines (CAIVs) have been developed over the past two decades by taking advantage of the segmented RNA genome of influenza and creating attenuated reassortants containing contemporary hemagglutinin (HA) and neuraminidase (NA) genes. These vaccines have been shown to be easily administered, safe and immunogenic in adults and children. Recent trials of a trivalent live attenuated CAIV (CAIV-T, tradename FluMist, Aviron, Mt. View, CA) in children have demonstrated greater than 85% efficacy against culture positive H3N2 and B influenza illness and complications, such as otitis media. CAIV-T also prevented shedding of H1N1 virus in 83% of vaccinated subjects after a monovalent CAIV challenge. Nasal IgA and serum HA inhibition (HAI) antibody produced by these vaccines have been associated with protection against infection, but protection may exist even in the absence of identifiable antibody response. Work to date documenting phenotypic and genetic stability, low likelihood of reactogenicity, infrequent transmissibility and attenuating properties of reassortants heralds promise for the broad use of this vaccine. Targeting children to receive this vaccine may now prove practical and may serve to reduce overall influenza morbidity, given the significant contribution of the pediatric age group of children to influenza illness burden and community spread. Studies of vaccine use in community settings will aid in determining the public health future of this approach.

Safety of the trivalent, cold-adapted influenza vaccine (CAIV-T) in children

The trivalent, cold-adapted influenza vaccine (CAIV-T, FluMist, Aviron, Mountain View, CA) is a live attenuated influenza virus vaccine that is administered by nasal spray. CAIV-T is efficacious in preventing influenza virus infection. The vaccine was submitted to the Food and Drug Administration for licensure in healthy children and adults. Universal immunization is being considered in children, and an effective vaccine with minimal adverse reactions is thus required. The published studies on the safety of CAIV-T in children reviewed in this article were clinical trials sponsored by the National Institutes of Health (NIH) conducted in children from 1975 to 1991, clinical trials from 1991 to 1993 sponsored by a cooperative agreement between NIH and Wyeth-Ayerst Research, and clinical trials from 1995 to the present sponsored by a cooperative agreement between NIH and Aviron. Safety assessments included the occurrence of: 1) specific influenza-like symptoms, unexpected symptoms, and use of medications within the first 10 days after vaccination; 2) acute illness and use of medication within 11 to 42 days postvaccination; 3) serious adverse events and rare events within 42 days after vaccination; 4) healthcare utilization within 14 days after vaccination; and 5) acute respiratory symptoms with annual sequential vaccine doses. CAIV-T was safe and well-tolerated. Transient, mild respiratory symptoms were observed in a minority (10%-15%) of children and primarily with the first CAIV-T dose. Vomiting and abdominal pain occurred in fewer than 2 percent of CAIV-T recipients. The gastrointestinal symptoms were mild and of short duration. An excess of illness or use of medication was not observed after the 10th day of vaccination. Sequential annual doses of CAIV-T were well-tolerated and not associated with increased reactogenicity. CAIV-T did not cause an increase in healthcare utilization. Thus CAIV-T is safe in healthy children and should complement the use of inactivated influenza vaccine, trivalent (IIV-T) in children with underlying chronic conditions.

Live attenuated vaccines against influenza; an historical review

Live attenuated vaccines administered directly to the respiratory tract offer the promise of providing more effective immunity against influenza than subunit or split inactivated vaccines. Evidence has accumulated in recent years that immunological responses relevant to both the prevention of and recovery from influenza are best induced by natural infection. The ease with which the genes of influenza viruses reassort when two or more viruses infect a single cell has been exploited as a means of rapidly producing attenuated vaccines. Donor strains that have been shown by extensive testing to be fully attenuated are used to co-infect cells with contemporary epidemic strains to produce reassortants with the required degree of avirulence and the surface antigens of the epidemic strain. Reassortants prepared from cold-adapted mutants of both influenza A and B viruses have been widely shown from clinical trials in both the United States and Russia over many years to be well tolerated in both adults and children and to be highly efficacious.

Influenza: vaccination and treatment

Few conditions exert such an enormous toll of absenteeism, suffering, medical consultations, hospitalization, death and economic loss as influenza. Patients at high risk of complications and mortality include the elderly and those with pre-existing cardiopulmonary disease. The outbreak in 1997 in Hong Kong, of avian H5N1 influenza in man, which resulted in six deaths among 18 hospitalized cases, and the recent isolation of H9N2 viruses from two children in Hong Kong, are reminders that preparation must be made for the next pandemic. Since the 1970s, efforts to control influenza have mostly focussed on the split product and surface antigen vaccines. These vaccines are of proven efficacy in healthy adults and are effective in elderly people with and without medical conditions putting them at high risk of complications and death following influenza infection. However, vaccine coverage is patchy and often low, and outbreaks of influenza are not uncommon in well-immunized residents of nursing homes. New vaccines and methods of vaccine delivery are being developed in attempts to overcome the limitations of existing vaccines. The antiviral drugs amantadine and rimantadine were developed in the 1960s, but have not been used widely due to their spectrum of activity, rapid emergence of resistance, and adverse effects associated with amantadine. The site of enzyme activity of the influenza neuraminidase is highly conserved between types, subtypes and strains of influenza and has emerged as the target of an exciting new class of antiviral agents that are effective both prophylactically and as therapy.

Safety, efficacy and effectiveness of the influenza virus vaccine, trivalent, types A and B, live, cold-adapted (CAIV-T) in healthy children and healthy adults

Influenza is a major cause of illness. We have assessed the safety, efficacy, and effectiveness of CAIV-T vaccine. A two year, multicenter, double-blind, placebo-controlled, efficacy field trial in pre-school aged children was conducted; 1602 enrolled in Year One and 1358 (85%) returned in Year Two. In both study years combined, the overall vaccine efficacy against culture-confirmed influenza was 92% (95% CI: 88, 94). The vaccine efficacy was 95% (95% CI: 62, 99) against lower respiratory illness, 94% (95% CI: 90, 96) against febrile illness and 96% (95% CI: 88, 99) against otitis media associated with culture-confirmed influenza. A multicenter, double-blind, placebo-controlled, effectiveness field trial was conducted in 4561 working adults aged 18 to 64 years. Episodes and days of febrile illness (FI), severe febrile illness (SFI), febrile upper respiratory illness (FURI), work loss, and health care use were assessed. Vaccination significantly reduced the numbers of SFI, 18.8% reduction (95% CI: 7, 29), and FURI, 26.3% reduction (95% CI: 13, 33); and led to fewer days of illness (22.9% reduction for FI, 27.3% reduction for SFI), fewer days of work lost (17.9% reduction for SFI, 28.4% for FURI), and fewer days of health care provider visits (24.8% for SFI, 40.9% for FURI). Prescription antibiotics and over-the-counter medications were also reduced. The vaccine was generally safe and well tolerated with no vaccine related serious adverse events. LAIV represents an additional important option for the control of influenza.

Promises and challenges of live-attenuated intranasal influenza vaccines across the age spectrum: a review

Despite the availability of inactivated influenza vaccines, influenza continues to cause considerable mortality in the elderly, and morbidity in all age groups. Cold-adapted, live-attenuated, intranasally administered influenza vaccines, first developed in the 1960s, have been tested in more than 10,000 volunteers and have been shown to be safe, well-tolerated, and immunogenic. Recent trials suggest that efficacy in children may be superior to that of inactivated vaccines, and efficacy in healthy adults may be similar to that of inactivated vaccines, although there are limited data comparing the two vaccines directly. Advantages of the live-attenuated vaccines include acceptability, ease of administration, and the potential for mass immunization. The possibility of substantially higher vaccination rates across all age groups brings promise for the development of herd immunity and greatly improved control of influenza in the future.

Effect of vitamin A therapy on serologic responses and viral load changes after influenza vaccination in children infected with the human immunodeficiency virus

Vitamin A administered to children infected with the human immunodeficiency virus before influenza vaccination in a double-blind randomized study did not enhance vaccine serologic responses but did dampen the increase in the human immunodeficiency virus viral load 14 days after immunization (vitamin A, decrease of 0.13 +/- 0.09 log(10) copies/mL; placebo, increase of 0.14 +/- 0.08, P =.02).

Efficacy of vaccination with live attenuated, cold-adapted, trivalent, intranasal influenza virus vaccine against a variant (A/Sydney) not contained in the vaccine

OBJECTIVE

To determine the safety, immunogenicity, and efficacy of revaccination of children with live attenuated influenza vaccine.

STUDY DESIGN

A 2-year multicenter, double-blind, placebo-controlled, efficacy field trial of live attenuated, cold-adapted trivalent influenza vaccine administered by nasal spray to children. This report summarizes year 2 results, a year in which the epidemic strain of influenza A/Sydney was not well matched to the vaccine strains. Each year, vaccine strains were antigenically equivalent to the contemporary inactivated influenza vaccine. In year 2, a single intranasal revaccination was administered. Active surveillance for influenza was conducted during the influenza season by means of viral cultures. Influenza cases were defined as illnesses with wild-type influenza virus isolated from respiratory secretions.

RESULTS

In year 2, 1358 (85%) children, 26 to 85 months of age, returned for revaccination. The intranasal vaccine was easily accepted, well tolerated, and immunogenic. Revaccination resulted in 82% to 100% of the vaccinated children in a subset studied for immunogenicity being seropositive as compared with 26% to 65% of placebo recipients, depending on the influenza strain tested. No serious adverse events were associated with the vaccine. In addition to the strains in the vaccine, antibody was induced to the variant strain A/Sydney/H3N2. In year 2, influenza A/Sydney/H3N2, a variant not contained in the vaccine, caused 66 of 70 cases of influenza A; nonetheless, intranasal vaccine was 86% efficacious in preventing A/Sydney influenza. Eight cases of lower respiratory tract disease were associated with A/Sydney influenza; all cases were in the placebo group.

CONCLUSIONS

This live attenuated, cold-adapted influenza vaccine was safe, immunogenic, and efficacious against influenza A/H3N2 (including a variant, A/Sydney, not contained in the vaccine) and influenza B. The characteristics of this vaccine make it suitable for routine use in children to prevent influenza.

Evaluation of trivalent, live, cold-adapted (CAIV-T) and inactivated (TIV) influenza vaccines in prevention of virus infection and illness following challenge of adults with wild-type influenza A (H1N1), A (H3N2), and B viruses

Trivalent, live, cold-adapted influenza vaccine (CAIV-T) is highly effective in the prevention of influenza in children, and a variety of monovalent and bivalent cold-adapted influenza vaccines have been efficacious in adults. In order to determine the efficacy of CAIV-T in healthy adults, we administered CAIV-T, trivalent inactivated influenza vaccine (TIV) or placebo to 103 adults in randomized double-blind fashion, and then challenged those subjects who had pre-screening serum hemagglutination-inhibition antibody titers of 1:8 or less with wild-type influenza viruses corresponding to the strains contained in the vaccine. CAIV-T was well tolerated. Upon challenge with wild-type influenza virus, laboratory documented influenza illness (respiratory symptoms with either isolation of wild-type influenza virus from nasal secretions or 4-fold and/or greater HAI antibody response to challenge) occurred in 14/31 (45%) placebo recipients, 4/32 (13%) TIV recipients, and 2/29 (7%) CAIV-T recipients. The estimated protective efficacy of CAIV-T was therefore 85% and of TIV was 71%. These results are consistent with those of previous studies using monovalent preparations of cold-adapted influenza vaccine in this model, and indicate that CAIV-T will be an effective means to prevent influenza illness in adults.

Influenza vaccines: present and future

Immunization is the most feasible method for preventing influenza. Vaccination against influenza is recommended for everyone 65 years of age and older and for persons less than 65 years of age who are at risk for developing complications of influenza. Immune correlates of protection have been established, and a global network is in place to monitor the appearance and circulation of antigenic variants of influenza viruses, as well as the appearance of novel subtypes of influenza A. Antigenic and genetic analyses of circulating viruses and testing of serum from vaccine recipients guide vaccine composition updates. The efficacy of influenza vaccines depends in part on the closeness of the antigenic match between the vaccine strain and the epidemic strain. Currently licensed influenza vaccines are trivalent, formalin-inactivated, egg-derived vaccines; their efficacy ranges from 70 to 90% in young, healthy populations when there is a close antigenic match between vaccine strains and epidemic strains. Development of intranasally administered alternative vaccines and improvement of the existing vaccine are areas of active research. A trivalent, ca live vaccine is the most promising LAIV candidate. In a field trial, efficacy rates of LAIV in young children were 96% against influenza A (H3N2) and 91% against influenza B. However, few data are available to compare this formulation of the trivalent ca live vaccine with the trivalent, inactivated vaccine. Influenza vaccine recommendations will most likely be revised on licensure of LAIV; each vaccine may offer distinct advantages in specific populations.

Is there a role for a mucosal influenza vaccine in the elderly?

Influenza infection is an acute respiratory disease with a high morbidity and significant mortality, particularly among the elderly and individuals with chronic diseases. The majority of countries now recommend annual influenza vaccination for all people aged 65 years or older, and for those with high risk conditions. Most commercially available influenza vaccines are administered systemically and while these are effective in children and young adults, efficacy levels in elderly individuals have been reported to be much lower. Mucosal vaccines may offer an improved vaccine strategy for protection of the elderly. As the influenza virus causes a respiratory infection, it is potentially more beneficial to administer a vaccine that will boost protection in the mucosal surfaces of the upper and lower respiratory tract. Mucosal influenza vaccines are aimed at stimulating protective immunity in the respiratory tract via oral or intranasal immunisation. This review examines our present knowledge of mucosal immunity and current strategies for mucosal vaccination. It also stresses that the use of serum antibody levels as a 'surrogate marker' for protection against influenza is potentially misleading; serum antibody, for example, may be a quite inappropriate marker to assess a mucosal vaccine. This marker does not reflect other immune responses to vaccination that are crucial for protection.

Evaluation of bivalent live attenuated influenza A vaccines in children 2 months to 3 years of age: safety, immunogenicity and dose-response

1126 children, 2 months to 3 years old, received a single intranasal dose of 10(4), 10(6), or 10(7) TCID50 of cold adapted (ca) A/Kawasaki/9/86 (H1N1) and A/Beijing/352/89 (H3N2) or placebo, in a double blind, placebo-controlled, safety and immunogenicity trial. No reactogenicity attributable to vaccine was demonstrated. A single bivalent 10(6) or 10(7) dose produced high rates of seroconversion to H1N1 (77%) and H3N2 (92%) in seronegative children > 6 months old; serologic responses were lower to H1N1 (P < 0.001) and H3N2 (P = 0.01) in younger infants. A single 10(6) dose of bivalent ca influenza A vaccine can be immunogenic in children, but response is age dependent.

Effect of influenza immunization on immunologic and virologic characteristics of pediatric patients infected with human immunodeficiency virus

OBJECTIVES

We evaluated the responses of HIV-infected children to a single dose of split-virus influenza vaccine and the relationship to viral load and other characteristics.

METHODS

Fifty-three HIV-infected children ages 1.8 to 13.2 years were given influenza vaccine for the 1994 to 1995 influenza season (Wyeth-Ayerst: A/Texas H1N1, A/Shangdong H3N2 and B/Panama). Immunologic and virologic factors were assessed at the time of and 2 to 10 weeks after immunization.

RESULTS

The differences between pre- and postimmunization CD4+ counts, CD4+:CD8+ ratios and viral load were not significant. Thirty-one of 53 children (58.4%) had a > 2-fold increase and 16 of 53 (30%) had a 4-fold rise in their postimmunization antibody titers for at least one component of the vaccine. Influenza immunization in the 1993 to 1994 flu season and administration of intravenous immunoglobulin around the time of immunization was not associated with immune response to the vaccine. Factors that were negatively associated with antibody response included increased time between samples (P = 0.004) and decreased preimmunization CD4+:CD8+ ratio (P = 0.02).

CONCLUSIONS

Influenza immunization in this population is safe, and a positive antibody response to influenza immunization is not associated with significant clinical events or change in HIV-1 plasma viral burden.

Studies on reactogenicity and immunogenicity of attenuated bivalent cold recombinant influenza type A (CRA) and inactivated trivalent influenza virus (TI) vaccines in infants and young children

Fifty-two infants seronegative to or without prior infection with influenza type A viruses were enrolled in a study to evaluate reactogenicity and immunogenicity of three bivalent cold recombinant type A (CRA) and two trivalent inactivated influenza (TI) vaccines. Controls consisted of infants receiving normal saline by nose drops (Pli.n.) or intramuscularly (Pli.m.). CRA and TI vaccines were monitored for local and systemic reactions after vaccination. Serum specimens obtained prior to and 6 weeks postvaccination were analysed for neutralizing antibody to influenza H1N1 and H3N2 viruses. CRA vaccines and Pli.n. recipients had similar numbers of acute respiratory infections and comparable rates of illnesses during the trial. Significantly fewer CRA vaccinees without an intercurrent viral infection had fever (0/16 versus 4/10, p = 0.04) and cough (4/16 versus 9/10, p = 0.002) than CRA vaccinees with a confirmed intercurrent viral infection. Recipients of TI vaccine and Pli.m. did not develop reactions at the injection site. For each of the CRA vaccines tested, a dominant CRA virus was identified. The dominant CRA viruses were isolated from a greater number of infants or for a longer duration than the non-dominant CRA viruses. All 14 non-dominant CRA viruses were recovered from infants within the first week after vaccination; 24 of 77 dominant CRA viruses were recovered more than 7 days after vaccination. The immunogenicity of CRA vaccines was not affected by a confirmed intercurrent viral infection or low titres of influenza-specific antibody.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunization of institutionalized asthmatic children and patients with psychomotor retardation using live attenuated cold-adapted reassortment influenza A H1N1, H3N2 and B vaccines

Live attenuated cold-adapted reassortant (CR) influenza virus vaccines were evaluated in institutionalized asthmatic children and severe psychomotor-retarded (SPR) patients. Almost all the vaccinees were seropositive to the vaccine strains before immunization. Trivalent CR vaccine (containing A H1N1 (CR-125), A H3N2 (CR-149) and B (CRB-117)), bivalent CR vaccine (CR-125 and CR-149) and monovalent CRB-117 were inoculated to 19 asthmatic children and 36 and 16 SPR patients, respectively. Overall 49, 22, and 11% of vaccinees were infected by A H1N1, A H3N2 or B vaccine viruses, respectively, as indicated by significant haemagglutination-inhibition (HI) antibody titre rises 4 weeks after inoculation. No severe adverse reactions associated with CR vaccination were observed in the handicapped patients. A nosocomial outbreak of influenza A H1N1 occurred in the ward with asthmatic children, but none of the 19 CR-trivalent vaccinees became infected. However, five of 20 non-vaccinees in the same ward, and ten of 30 vaccinees in another ward that received inactivated split vaccine became infected. The CR vaccines demonstrated significant protective effects against natural exposure to the A H1N1 virus, and were well tolerated and safe when given to patients with bronchial asthma and severe psychomotor retardation.

The attenuation phenotype conferred by the M gene of the influenza A/Ann Arbor/6/60 cold-adapted virus (H2N2) on the A/Korea/82 (H3N2) reassortant virus results from a gene constellation effect

A single gene reassortant (SGR) virus that derived its M gene from the attenuated influenza A/Ann Arbor/6/60 cold-adapted (CA) donor virus and the remaining genes from the A/Korea/82 (H3N2) wild type (WT) virus (designated A/Korea/82 CA M-SGR) was previously shown to be attenuated in mice, hamsters, ferrets, and humans. The attenuation (ATT) phenotype of this SGR virus could result directly from an altered function of the mutant M gene product of the A/Ann Arbor/6/60 CA virus, which differs from the M gene of the A/Ann Arbor/6/60 WT virus at only one amino acid or, indirectly from a gene constellation effect in which ATT results from an inefficient interaction between the products of the M gene of the A/Ann Arbor/6/60 virus and other genes of the A/Korea/82 virus. Several lines of evidence from the present study are consistent with our interpretation that the ATT phenotype of the A/Korea/82 CA M-SGR results from a gene constellation effect. First, the A/Korea/82 CA M-SGR and an A/Korea/82 SGR containing the A/Ann Arbor/6/60 WT M gene were each restricted in replication in the upper and lower respiratory tract of mice compared with the A/Korea/82 WT virus. Second, an A/Udorn/72 CA M-SGR containing the M gene from the A/Ann Arbor/6/60 CA donor virus in a background of other genes derived from the A/Udorn/72 (H3N2) WT virus was not attenuated in the respiratory tract of mice. These data suggest that the change in the amino acid sequence of the M gene product from the A/Ann Arbor/6/60 WT to CA virus is not responsible for the ATT phenotype of the A/Korea/82 CA M-SGR. In addition, evidence of the genetic instability of the A/Korea/82 CA M-SGR is presented, specifically, an extragenic mutation that results in loss of the ATT phenotype. The implications of these findings for the ATT phenotype of the live attenuated reassortant viruses derived from the A/Ann Arbor/6/60 CA donor virus are discussed.

Reduced infectivity of cold-adapted influenza A H1N1 viruses in the elderly: correlation with serum and local antibodies

OBJECTIVE

To compare young and elderly adults in terms of their immune responses and rates of infection following intranasal vaccination with a live attenuated influenza virus.

DESIGN

Time series, comparing outcomes in young and elderly convenience sample.

METHOD

Retrospective laboratory analysis of serum and nasal wash specimens collected during prior studies in which young or elderly volunteers had been inoculated with cold-adapted influenza A/Kawasaki/86 (H1N1) reassortant virus.

SETTING

Johns Hopkins Center for Immunization Research.

PARTICIPANTS

Healthy young and elderly adults with pre-vaccination serum hemagglutination inhibition (HAI) antibody titers less than or equal to 1:8.

OUTCOME MEASUREMENTS

Antibody responses in serum and nasal washes.

MAIN RESULTS

The proportion of vaccinees who developed any serum or local antibody response was higher in young compared with elderly subjects (20/20 vs 5/14, P less than 0.0005). Resistance to infection with cold-adapted virus correlated with pre-vaccination levels of serum immunoglobulin G (IgG), serum IgA, and nasal wash IgA antibody to whole virus antigen. Age was highly correlated with a lack of response to vaccine by simple regression, but not when data were adjusted for pre-existing antibody levels.

CONCLUSIONS

Cold-adapted reassortant influenza A H1N1 viruses achieve lower rates of infection in elderly than young adults, primarily due to age-related differences in preexisting levels of immunity which may not be reflected by HAI titer.

New aspects of influenza viruses

Influenza virus infections continue to cause substantial morbidity and mortality with a worldwide social and economic impact. The past five years have seen dramatic advances in our understanding of viral replication, evolution, and antigenic variation. Genetic analyses have clarified relationships between human and animal influenza virus strains, demonstrating the potential for the appearance of new pandemic reassortants as hemagglutinin and neuraminidase genes are exchanged in an intermediate host. Clinical trials of candidate live attenuated influenza virus vaccines have shown the cold-adapted reassortants to be a promising alternative to the currently available inactivated virus preparations. Modern molecular techniques have allowed serious consideration of new approaches to the development of antiviral agents and vaccines as the functions of the viral genes and proteins are further elucidated. The development of techniques whereby the genes of influenza viruses can be specifically altered to investigate those functions will undoubtedly accelerate the pace at which our knowledge expands.

Influenza: status and prospects for its prevention, therapy, and control

This article describes current knowledge of the molecular properties of orthomyxoviruses, their epidemiology, and approaches to the control of influenza. The host's response to infection, approaches to prevent infection through vaccination, and the use of antiviral agents to treat or prevent this important infection are covered.

Use of live cold-adapted influenza A H1N1 and H3N2 virus vaccines in seropositive adults

To investigate the immunogenicity and protective efficacy of cold-adapted influenza vaccine in individuals with underlying immunity to influenza A virus, we administered cold-adapted H1N1 and H3N2 vaccines to adults with prevaccination serum hemagglutination inhibition antibody titers of 1:16 or more and challenged them 1 month afterwards with homologous wild-type influenza A virus. Both cold-adapted vaccines were immunogenic in seropositive adults. In addition, individuals receiving cold-adapted vaccines had lower rates of virus shedding and illness following challenge with wild-type influenza virus than did unvaccinated seropositive volunteers.

Evaluation of cold-recombinant influenza A/Korea (CR-59) virus vaccine in infants

Twenty-four infants 5 to 13 months of age were intranasally vaccinated with a live cold-recombinant influenza A/Korea (CR-59, H3N2) virus vaccine. Nineteen infants served as controls. The inocula ranged from 10(3.2) to 10(6.2) 50% tissue culture infective doses (TCID50) per infant. Zero of six, one of four, seven of ten, and four of four infants receiving 10(3.2), 10(4.2), 10(5.2), and 10(6.2) TCID50, respectively, were infected by the intranasal vaccine. The amount of virus required to infect 50% of infants was calculated to be 10(4.6) TCID50. The occurrence of fever, respiratory illness, and otitis media was common among both controls and vaccinees in the postinoculation period. Maternal antibody was present in low titers in some infants and did not inhibit replication of the vaccine virus.

Analysis of virus and host factors in a study of A/Peking/2/79 (H3N2) cold-adapted vaccine recombinant in which vaccine-associated illness occurred in normal volunteers

Live attenuated cold-adapted influenza vaccine is undergoing evaluation in man. Several strains have proven to be safe, immunogenic, nontransmissible, and protective against experimental challenge. In this study of A/Peking/2/79(H3N2), with six internal genes from the cold-adapted (Ca) parent A/Ann Arbor/6/60(H2N2), we encountered at the highest input multiplicity, 28% illness rate among individuals infected with vaccine. Reversion to wild type and excessive viral replication did not occur. Physical characteristics of the vaccine were similar to nonreactogenic vaccine A/Washington/897/80(H3N2). At ten- and 100-fold lower input multiplicities, infection frequency was maintained, but reactions did not occur. We compared the observations in this study with those made in a similar study of A/Scotland/840/74(H3N2), a cold-adapted vaccine with five genes from the Ca parent in which reactogenicity also was noted. The dose of vaccine virus in relation to tissue culture infectious doses required to infect 50% of susceptibles (HID50) was proportionally lower for both A/Peking/2/79(H3N2) and A/Scotland/80(H3N2). Hence, when the vaccine was undiluted the recipients were inoculated with more than 100 HID50. We concluded that the very high input could be avoided if vaccines were screened beginning at 1/1,000 of maximum titers. Ca vaccines must be safe before they undergo field trials.

Four viral genes independently contribute to attenuation of live influenza A/Ann Arbor/6/60 (H2N2) cold-adapted reassortant virus vaccines

Clinical studies previously demonstrated that live influenza A virus vaccines derived by genetic reassortment from the mating of influenza A/Ann Arbor/6/60 (H2N2) cold-adapted (ca) donor virus with epidemic wild-type influenza A viruses are reproducibly safe, infectious, immunogenic, and efficacious in the prevention of illness caused by challenge with virulent wild-type virus. These influenza A reassortant virus vaccines also express the ca and temperature sensitivity (ts) phenotypes in vitro, but the genes of the ca virus parent which specify the ca, ts, and attenuation (att) phenotypes have not adequately been defined. To identify the genes associated with each of these phenotypes, we isolated six single-gene substitution reassortant viruses, each of which inherited only one RNA segment from the ca parent virus and the remaining seven RNA segments from the A/Korea/1/82 (H3N2) wild-type virus parent. These were evaluated in vitro for their ca and ts phenotypes and in ferrets, hamsters, and seronegative adult volunteers for the att phenotype. We found that the polymerase PA gene of the ca parent specifies the ca phenotype and that the PB2 and PB1 genes independently specify the ts phenotype. The PA, M, PB2, and PB1 genes of the ca donor virus each contribute to the att phenotype. The finding that four genes of the ca donor virus contribute to the att phenotype provides a partial explanation for the observed phenotypic stability of ca reassortant viruses following replication in humans.

Relative antigenicity in mice of H1N1, H3N2 and B strains present in inactivated influenza virus vaccines

The results of a study on serum HAI and neutralizing antibodies induced in mice by whole influenza virus vaccines containing A/Brazil/11/78 (H1N1), A/Bangkok/1/79 (H3N2) and B/Singapore/222/79 viruses are reported. According to the GMT of HAI, the antigenic potency of the three vaccine strains appear to be different. The A/Brazil/11/78 antigen induced the lowest HAI antibody responses and the A/Bangkok/1/79 antigen the greatest. This behaviour, with a few exceptions, was noted regardless of the HA amount (0.08 microgram 0.4 microgram, 2 micrograms) of each strain present in the vaccine, the number of doses (one or two), or the kind of preparation (monovalent or trivalent). The data obtained with the neutralization test with vaccines with medium HA content are concordant with previous findings. On the basis of the ratios of the GMT of the neutralizing antibodies to the GMT of the HAI antibodies, it was concluded that the HAI antibodies to A/Bangkok/1/79 antigen possess, on the whole, a neutralizing activity that is higher than that found for the HAI antibodies to A/Brazil/11/78 and B/Singapore/222/79 strains. For the latter strains, the neutralizing activity increased after the second dose. The observation of the different degrees of antigenicity of the three vaccine strains suggests that, with currently used inactivated influenza virus vaccines containing equivalent amounts of all three antigens, the dosage should be taken into consideration when the vaccines are used for subjects lacking in previous exposure to vaccine strains.