Results of a study of new preparations of inactivated whole-virion influenza vaccines for the protection of children in the USSR

The safety, reactogenic properties and antigenic potency of inactivated whole-virion influenza vaccines produced in the USSR were studied on 1,117 schoolchildren in limited coded clinico-immunological observations. Inactivated chromatographic influenza vaccine obtained from strain A/Texas/1/77 (H3N2) and a variant of this vaccine, developed specially for children and obtained from strains A/Texas/1/77 and B/Leningrad/76, were used for immunization. Both preparations were introduced intradermally in a single injection in a volume of 0.1-0.2 ml by means of bi-3 jet injector. The content of hemagglutinin in this volume varied from 3.0 to 8.0 micrograms. Clinico-laboratory investigations demonstrated the safety of mono- and bivalent inactivated whole-virion influenza vaccine administered intradermally in a single injection to children of school age. The vaccines showed low reactogenicity and high antigenic potency in children aged 7-10 and 11-14 years, and the optimal doses of the preparations were selected for children of different age groups. The distinct prophylactic effectiveness of inactivated chemical chromatographic influenza vaccines in children aged 11-14 years was revealed 11 months after immunization, the index of immunological effectiveness being 1.7.     

The evaluation of the reactogenicity and immunological activity of an inactivated 3-component influenza vaccine with an elevated hemagglutinin concentration in the inoculation dosage

In this work the reactogenic properties and antigenic potency of inactivated trivalent influenza vaccine, obtained by elution and centrifugation and containing up to 9-11 micrograms of hemagglutinin for influenza viruses A(H1N1) and A(H3N2) and up to 14 micrograms for influenza virus B, were studied. The reactogenicity of the preparation was found to correspond to the regulations. The immunogenic potency characteristics of individual batches of this trivaccine were higher than the immunogenicity of divaccines, but did not meet the requirements of technical specifications.     

Assessment of the prophylactic effectiveness of an inactivated influenza vaccine by immunizing schoolchildren in the springtime

To evaluate the prophylactic effectiveness of influenza inactivated chromatographic vaccine, limited epidemiological observations were made on school children aged 11-14 years in Leningrad, in the autumn of 1981 and the spring of 1982. For immunization, made in a single administration, the vaccine composed of A (H3N2) + +A (H1N1) and containing 3.0-3.4 micrograms of hemagglutinin of each component per 0.2 ml of the preparation was used. Altogether 6928 schoolchildren were under observation; of these, 3686 children were immunized and 3242 children received placebo. The results of questioning and the analysis of morbidity rate among the schoolchildren, both immunized and receiving placebo, showed the safety and low reactogenicity of the vaccine irrespective of the time of the immunization campaign. The immunogenic potency of the preparation, as indicated by all observation results, proved to be higher in spring, than in autumn. The data thus obtained indicate that children immunized in spring were better protected and retained a higher level of protection within 12 months after immunization. The shift of the time of the immunization campaign from autumn to spring increased the immune layer in the groups of children by 16.5%. In 10 months after spring immunization the morbidity rate in influenza and acute respiratory diseases among the vaccinees was found to decrease 1.7 times.     

Characteristics of the clinical and immunologic safety of inactivated influenza vaccines in children undergoing multiple immunizations

In a strictly controlled epidemiological trial on 12,643 school children aged 11-14 years the reactogenic properties and safety of killed influenza chromatographic vaccine under the conditions of multiple immunization were studied. A single immunization dose of the vaccine (0.2 ml) contained the hemagglutinins of influenza viruses A/Philippines/82 (H3N3) and A/Kiev/59/79 (H1N1), 3.5 micrograms each. The preparation was introduced by means of a jet injector. The vaccine was shown to be clinically and immunologically safe under the conditions of the regular multiple immunization of children over the period of 4 years.     

Results of a study of a live intranasal influenza vaccine in the immunization of children 3 to 15 years old

A total of 10,971 children aged 3-15 years were immunized with live influenza vaccine (the variant intended for children), type A (H1N1). The vaccine proved to be nonreactogenic and produced no harmful effect on the child organism. The genetic stability of the vaccine strain and its high immunogenic activity were shown.     

Antigenic anachronism of the influenza A(H2N2) viruses in Leningrad in 1980. I. The epidemiological and serological characteristics of the influenzal infection caused by A/Leningrad/80 (H2N2) viruses

In April-May 1980 a number of unrelated outbreaks of influenza-like diseases were registered in Leningrad in an infant home (50 out of 68 children under observation, aged 3 months to 2 years, were affected) and among the pupils of a boarding school (13 out of 50 adolescents under observation, aged 15-17 years, were affected). 5 strains of influenza A virus were isolated from 3 sick children and 1 clinically healthy child. A similar virus was isolated from a sick adolescent in a boarding school, as well as from a female patient aged 24 years at a domiciliary focus of infection (a sporadic case). In the subsequent laboratory investigation all these 7 strains were identified as viruses A/H2N2. Isolated cases of seroconversion to hemagglutinin H2 were definitely registered in 6 patients during February--May 1980. In 3 cases, including the 24-year old female patient with an acute respiratory disease, seroconversion to hemagglutinin H2 was observed in combination with the release of influenza viruses A/H2N2 from these patients. 2 influenza virus strains with this antigenic characteristic were isolated from a young female patient at an interval of 3 days. Among the patients admitted to the clinics of the Research Institute of Influenza in Leningrad on account of acute respiratory diseases isolated cases of diagnostically significant seroconversion to hemagglutinin H2 constituted 3.5% among children and 4.5% among adults. The study of the level of antihemagglutinins in the population revealed that in 1980 persons aged 18-50 years showed a high level of antihemagglutinins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunologic response to the influenza virus neuraminidase is influenced by prior experience with the associated viral hemagglutinin. I. Studies in human vaccinees

Analysis of an earlier study of H3N2 and H7N2 inactivated influenza vaccines in schoolchildren demonstrated a greater viral neuraminidase (NA) immunogenicity of the vaccine containing the H7 hemagglutinin (HA) antigen to which they had not been primed, despite the lesser NA antigen content of that vaccine. Thus, prior experience with the influenza viral HA appeared to have a negative influence on immune response to NA, the associated external glycoprotein, presumably on the basis of intermolecular antigenic competition. In a second study, sequential immunologic response to influenza viral NA was compared in college students who were immunized with either conventional commercial vaccine or an antigenic reassortant H7N1 vaccine, and who subsequently experienced natural infection with an H1N1 influenza virus. Although both vaccines were only marginally immunogenic in inducing NA antibody response in seronegative subjects, in vaccinees initially seropositive for HA antibody significant NA antibody titer increases occurred with H7N1 vaccine. Subsequent natural infection boosted NA antibody less effectively in the population previously primed by natural infection than in initially seronegative subjects primed by H7N1 vaccination. It is suggested that primary immunization monospecific for influenza viral NA may alter the subsequent pattern of immune response to one more favorable to the induction of NA antibody when virus is encountered.     

Adsorbed influenza chemical vaccine in the immunization of schoolchildren

When used for the immunization of healthy children aged 7-14 year, adsorbed chemical influenza vaccine produced at the Mechnikov Research Institute for Vaccines and Sera in Ufa has proved to be safe, faintly reactogenic and antigenically very potent. The optimum doses for immunizing children aged 7-10 and 11-14 years have been selected.     

The results of state trials of inactivated influenza vaccines for children

Controlled epidemiological surveillance covering the total number of 13,355 schoolchildren aged 11-14 years and adolescents was carried out with a view to compare the efficacies of inactivated influenza vaccines. The children were immunized intradermally in a single injection with inactivated influenza vaccines containing A (H3N2) and A (H1N1) hemagglutinins, 3.5 micrograms per 0.2 ml of the preparation each. The studies demonstrated the safety and low reactogenicity of these vaccines, as well as their high antigenic potency. In 1984 during mixed influenza B + A (H1N1) epidemic the preparations produced a pronounced prophylactic effect: the efficacy indices were 1.6-1.9 (p less than 0.001). The results obtained in these studies made it possible to recommend two inactivated influenza vaccines (chromatographic and centrifugal) for practical medicine with the aim of protecting children aged 11 years and over from influenza.     

Evaluation of the reactogenic and immunogenic properties of meningococcal vaccines

The results of the study of the reactogenic and immunogenic properties of meningococcal polysaccharide A + C vaccine in the controlled epidemiological trial, with regard to variations depending on the initial immunological characteristics of vaccinees in terms of the levels of antibodies to the polysaccharides contained in the vaccine, are presented. The study was made on school children: 303 of them were immunized with the meningococcal vaccine under test, and 229 (controls) with adsorbed diphtheria-tetanus toxoid. This study revealed that the reactogenic properties of the preparation were more pronounced in those children whose blood sera had been found to contain no antibodies to polysaccharides A and C prior to immunization. The immunological properties were more pronounced with respect to polysaccharide A. The titer of antibodies to polysaccharide A was found to depend on the previous immunological status of the child, which was indicative of the booster effect produced by the vaccine. The data obtained in the study suggest that the evaluation of the reactogenic and immunogenic properties of newly developed prophylactic preparations should be made with due regard for the previous immunological status of vaccinees in respect to the antigens contained in the meningococcal vaccine under test.     

Cross-neutralizing antibodies to pandemic 2009 H1N1 and recent seasonal H1N1 influenza A strains influenced by a mutation in hemagglutinin subunit 2

Pandemic 2009 H1N1 influenza A virus (2009 H1N1) differs from H1N1 strains that circulated in the past 50 years, but resembles the A/New Jersey/1976 H1N1 strain used in the 1976 swine influenza vaccine. We investigated whether sera from persons immunized with the 1976 swine influenza or recent seasonal influenza vaccines, or both, neutralize 2009 H1N1. Using retroviral pseudovirions bearing hemagglutinins on their surface (HA-pseudotypes), we found that 77% of the sera collected in 1976 after immunization with the A/New Jersey/1976 H1N1 swine influenza vaccine neutralized 2009 H1N1. Forty five percent also neutralized A/New Caledonia/20/1999 H1N1, a strain used in seasonal influenza vaccines during the 2000/01-2006/07 seasons. Among adults aged 48-64 who received the swine influenza vaccine in 1976 and recent seasonal influenza vaccines during the 2004/05-2008/09 seasons, 83% had sera that neutralized 2009 H1N1. However, 68% of age-matched subjects who received the same seasonal influenza vaccines, but did not receive the 1976 swine influenza vaccine, also had sera that neutralized 2009 H1N1. Sera from both 1976 and contemporary cohorts frequently had cross-neutralizing antibodies to 2009 H1N1 and A/New Caledonia/20/1999 that mapped to hemagglutinin subunit 2 (HA2). A conservative mutation in HA2 corresponding to a residue in the A/Solomon Islands/3/2006 and A/Brisbane/59/2007 H1N1 strains that circulated in the 2006/07 and 2007/08 influenza seasons, respectively, abrogated this neutralization. These findings highlight a cross-neutralization determinant influenced by a point mutation in HA2 and suggest that HA2 may be evolving under direct or indirect immune pressure.     

2009年中国流行的甲型流感病毒（H1N1）血凝素特征分析

目的研究甲型流感病毒（H1N1）暴发流行以来中国各地甲型流感病毒血凝素（HA）的特征。方法搜索甲型流感病毒（H1N1）暴发流行以来中国各地报道的血凝素（HA）的氨基酸序列,比较当年不同时期血凝素（HA）的氨基酸序列的变化,并比较2009年报道的血凝素（HA）的氨基酸序列和2008年、2007年报道的血凝素（HA）的氨基酸序列作比较,以分析和前2年血凝素（HA）氨基酸序列相比所发生的变化。结果2009年中国各地甲型流感病毒（H1N1）的血凝素（HA）的氨基酸序列（人源）的同源性为99%-100%,但和2008年以及2007年的同源性非常低,分别为70%-77%和71%-90%。结论2009年暴发流行的甲型流感病毒（H1N1）的血凝素氨基酸序列较往年发生了很大程度的变异,这可能是今年甲型流感病毒（H1N1）暴发流行的主要原因。     

Safety, reactogenicity and immunological activity of a group A meningococcal polysaccharide vaccine for children 1-4 years old

In the controlled trial carried out among children aged 1-4 years, the safety, reactogenicity and immunological potency of group A meningococcal polysaccharide vaccine produced at the Gabrichevski? Research Institute of Epidemiology and Microbiology (Moscow) were studied. The vaccine under test was introduced in two doses containing 15 and 25 micrograms of meningococcal polysaccharide. Both doses were shown to be safe, faintly reactogenic and immunologically potent. Systemic reactions were manifested by a transient rise in temperature to subfebrile levels in 19% and to 37.8-38.2 degrees C in 4.7% of the vaccinees. The temperature dropped to the normal level by the end of the first day following vaccination. At the site of injection skin hyperemia up to 2-3 cm in diameter was registered in 74% and up to 5-6 cm in diameter, in 6% of the vaccinees. Hyperemia disappeared on day 2 after vaccination. The production of antibodies to group A meningococcal polysaccharide occurred in response to both doses under test, and the elevated antibody level (in comparison to the initial one) was retained perceptibly longer in response to a dose of 25 micrograms; this dose, considering its low reactogenicity, was chosen as the optimal dose for children of the above age group.     

Immunological effectiveness of a dried group-A meningococcal polysaccharide vaccine

The immunological effectiveness of dried group A meningococcal polysaccharide vaccine, developed at the Gabrichevsky Research Institute of Epidemiology and Microbiology, Moscow, for children aged 5-14 years was studied. The intensiveness of the immune response of children to 0.5 ml of the vaccine introduced in a single injection was evaluated by a rise in the level of agglutinating antibodies to group A meningococcal polysaccharide in the sera of the vaccinees 3-4 weeks after immunization with the following optimum doses: 25 micrograms for children aged 5-8 years, 50 micrograms for children aged 9-13 years and 75 micrograms for children aged 14 years and over. The vaccine was shown to be highly immunogenic. Antibodies to group A meningococcal polysaccharide were identified as IgM. These antibodies in a titer of 1:40 and higher could be detected in 90% of the vaccinated children in the younger age group, 7 months after immunization.     

Effectiveness of the 2012/13 Trivalent Live and Inactivated Influenza Vaccines in Children and Adolescents in Saxony-Anhalt,Germany: A Test-Negative Case-Control Study

A live attenuated influenza vaccine has been available in Germany since the influenza season 2012/13, which is approved for children aged 2-17 years. Using data from our laboratory-based surveillance system, we described the circulation of influenza and non-influenza respiratory viruses during the influenza season 2012/13 in Saxony-Anhalt. We estimated the effectiveness of live and inactivated trivalent influenza vaccines in preventing laboratory-confirmed cases among children and adolescents. From week 40/2012 to 19/2013, sentinel paediatricians systematically swabbed acute respiratory illness patients for testing of influenza and 5 non-influenza viruses by PCR. We compared influenza cases and influenza-negative controls. Among children aged 2-17 years, we calculated overall and vaccine type-specific effectiveness against laboratory-confirmed influenza, stratified by age group (2-6; 7-17 years). We used multivariable logistic regression to adjust estimates for age group, sex and month of illness. Out of 1,307 specimens, 647 (35%) were positive for influenza viruses and 189 (15%) for at least one of the tested non-influenza viruses. For vaccine effectiveness estimation, we included 834 patients (mean age 7.3 years, 53% males) in our analysis. Of 347 (42%) influenza-positive specimens, 61 (18%) were positive for A(H1N1)pdm09, 112 (32%) for A(H3N2) and 174 (50%) for influenza B virus. The adjusted overall vaccine effectiveness including both age groups was 38% (95% CI: 0.8-61%). The adjusted effectiveness for inactivated vaccines was 37% (95% CI: -35-70%) and for live vaccines 84% (95% CI: 45-95%). Effectiveness for the live vaccine was higher in 2-6 year-old children (90%, 95% CI: 20-99%) than in children aged 7-17 years (74%, 95% CI: -32-95%). Our study of the strong influenza season in 2012/13 suggests a high preventive effect of live attenuated influenza vaccine especially among young children, which could not be reached by inactivated vaccines. We recommend the use of live attenuated influenza vaccines in children unless there are contraindications.     

Evaluation of the efficacy of split-product trivalent A(H1N1), A(H3N2), and B influenza vaccines: protective efficacy

A total of 1,995 primary school children (1,464 vaccinees and 531 non-vaccinees) were studied to evaluate the protective efficacy of Tween-ether split trivalent A(H1N1), A(H3N2), and B influenza vaccines by comparison of the incidence of confirmed infection in two groups during 1980 to 1984. During the study period, epidemics caused by antigenically different influenza viruses, that is A(H1N1) epidemics in 1981 and 1984, a B epidemic in 1982 and an A(H3N2) epidemic in 1983, were experienced, and at the same time strains changed by antigenic drift were frequently isolated. In these epidemics, 61% to 87% of the children reported respiratory illnesses and 18% to 48% of the illnesses were influenza confirmed by seroconversion. Throughout these four epidemics, the incidence of confirmed infection among the vaccinees (7.8% to 33.8%) was 6.5% to 34.8% lower than that among the nonvaccinees (35.4% to 51.6%), demonstrating that the vaccine was effective (X2 = 76.34, P less than 0.001). However, this effectiveness was not seen in an epidemic in one of the entrant schools in 1984, possibly caused by a strain with intense antigenic drift. On the basis of data on incidence of various symptoms, duration of fever and the number of days of absence from class, it was considered that clinical symptoms in the vaccinees were milder than those in the nonvaccinees. When the titers of hemagglutination-inhibiting (HAI) antibody against the vaccine strains were measured, the protective level of HAI antibody giving less than or equal to 50% incidence of infection was 1:64, but it increased to 1:256 in the 1984 epidemic, reflecting the high rate of isolates with intense antigenic drift.     

Comparative clinical trial of vaccines against avian influenza

Scientic-production association "Microgen" has finished 1st phase of clinical trials of candidate vaccines against avian influenza in order to assess their reactogenicity, safety, and immunogenicity. Two vaccines constructed from NIBRG-14 vaccine strain [A/Vietnam/1 194/2004 (H5N1)], obtained from World Health Organization, were studied: "OrniFlu" (inactivated subunit influenza vaccine adsorbed on aluminium hydroxide) and inactivated polymer-subunit influenza vaccine with polyoxydonium (IPSIV). Clinical trial of the vaccines with different quantity of antigen (15, 30, and 45 mcg of H5N1 virus hemagglutinin) was carried out in Influenza Research Institute (St. Petersburg) and in Mechnikov Research Institute of Vaccines and Sera (Moscow). Analysis of results allowed to conclude that both vaccines were safe, well tolerated and characterized by low reactogenicity. Two-doses vaccination schedule was needed to meet required seroconversion and seroprotection rates (> or =1:40 in > or =70% of vaccinated volunteers). "Orni-Flu" vaccine containing 15 mcg of hemagglutinin and optimal quantity of aluminium hydroxide (0.5 mg) in one dose as well as IPSIV containing 45 mcg of hemagglutinin and 0.75 mg of polyoxydonium in one dose were most immunogenic after 2 doses - seroprotection rates in microneutralization assay were 72.2% and 77.0% respectively. Marked influence of aluminium hydroxide content on immunogenicity of the "OrniFlu" vaccine was confirmed in the study. Optimal quantity of adjuvant was 0.5 mg per dose. According to basic concept of vaccine development, preference is given to vaccine that under minimal quantity of antigen induces sufficient specific immune response and is safe in volunteers. "OrniFlu" vaccine containing 15 mcg of H5N1 virus hemagglutinin and optimal quantity of aluminium hydroxide (0.5 mg) corresponded to these requirements that allowed researchers to recommend it for clinical trials of 2nd phase.     

Phase I evaluation of intranasal trivalent inactivated influenza vaccine with nontoxigenic Escherichia coli enterotoxin and novel biovector as mucosal adjuvants, using adult volunteers

Trivalent influenza virus A/Duck/Singapore (H5N3), A/Panama (H3N2), and B/Guandong vaccine preparations were used in a randomized, controlled, dose-ranging phase I study. The vaccines were prepared from highly purified hemagglutinin and neuraminidase from influenza viruses propagated in embryonated chicken eggs and inactivated with formaldehyde. We assigned 100 participants to six vaccine groups, as follows. Three intranasally vaccinated groups received 7.5-microg doses of hemagglutinin from each virus strain with either 3, 10, or 30 microg of heat-labile Escherichia coli enterotoxin (LTK63) and 990 microg of a supramolecular biovector; one intranasally vaccinated group was given 7.5-microg doses of hemagglutinin with 30 microg of LTK63 without the biovector; and another intranasally vaccinated group received saline solution as a placebo. The final group received an intramuscular vaccine containing 15 microg hemagglutinin from each strain with MF59 adjuvant. The immunogenicity of two intranasal doses, delivered by syringe as drops into both nostrils with an interval of 1 week between, was compared with that of two inoculations by intramuscular delivery 3 weeks apart. The intramuscular and intranasal vaccine formulations were both immunogenic but stimulated different limbs of the immune system. The largest increase in circulating antibodies occurred in response to intramuscular vaccination; the largest mucosal immunoglobulin A (IgA) response occurred in response to mucosal vaccination. Current licensing criteria for influenza vaccines in the European Union were satisfied by serum hemagglutination inhibition responses to A/Panama and B/Guandong hemagglutinins given with MF59 adjuvant by injection and to B/Guandong hemagglutinin given intranasally with the highest dose of LTK63 and the biovector. Geometric mean serum antibody titers by hemagglutination inhibition and microneutralization were significantly higher for each virus strain at 3 and 6 weeks in recipients of the intramuscular vaccine than in recipients of the intranasal vaccine. The immunogenicity of the intranasally delivered experimental vaccine varied by influenza virus strain. Mucosal IgA responses to A/Duck/Singapore (H5N3), A/Panama (H3N2), and B/Guandong were highest in participants given 30 microg LTK63 with the biovector, occurring in 7/15 (47%; P=0.0103), 8/15 (53%; P=0.0362), and 14/15 (93%; P=0.0033) participants, respectively, compared to the placebo group. The addition of the biovector to the vaccine given with 30 microg LTK63 enhanced mucosal IgA responses to A/Duck/Singapore (H5N3) (P=0.0491) and B/Guandong (P=0.0028) but not to A/Panama (H3N2). All vaccines were well tolerated.     

Construction and comparison of different source neuraminidase candidate vaccine strains for human infection with Eurasian avian-like influenza H1N1 virus

Human infections with Eurasian avian-like swine influenza H1N1 viruses have been reported in China in past years. One case resulted in death and others were mild case. In 2016, the World Health Organization recommended the use of A/Hunan/42443/2015(H1N1) virus to construct the first candidate vaccine strain for Eurasian avian-like swine influenza H1N1 viruses. Previous reports showed that the neuraminidase of A/Puerto Rico/8/34(H1N1) might improve the viral yield of reassortant viruses. Therefore, we constructed two reassortant candidate vaccine viruses of A/Hunan/42443/2015(H1N1) by reverse genetic technology, with (6+2) and (7+1) gene constitution, respectively. The (6+2) virus had hemagglutinin and neuraminidase from A/Hunan/42443/2015, and the (7+1) one had hemagglutinin from A/Hunan/42443/2015, while all the other genes were from A/Puerto Rico/8/34. Our data revealed that although the neuraminidase of the (7+1) virus was from high yield A/Puerto Rico/8/34, the hemagglutination titer and the hemagglutinin protein content of the (7+1) virus was not higher than that of the (6+2) virus. Both of the (7+1) and (6+2) viruses reached a similar level to that of A/Puerto Rico/8/34 at the usual harvest time in vitro. Therefore, both reassortant viruses are potential candidate vaccine viruses, which could contribute to pandemic preparedness.     

Basic results of a committee trial of the new vaccine Grippovac SE-AZh

In the trial of the trivalent subunit influenza vaccine Grippovac CE-AK observations on children aged 3-6 years were made. The preparation showed insignificant reactogenicity and moderate antigenic potency. The trial established that at the period of the epidemic rise of influenza B morbidity the vaccine showed, according to the data of the clinical diagnosis of influenza, insignificant effectiveness, its index of effectiveness (IE) being 1.08; according to the data of the serological diagnosis of influenza, only the A (H1N1) component of the vaccine was found to have IE equal to 1.58.