Safety and serum distribution of anti-SARS-CoV-2 monoclonal antibody MAD0004J08 after intramuscular injection.

The emerging threat represented by SARS-CoV-2 variants, demands the development of therapies for better clinical management of COVID-19. MAD0004J08 is a potent Fc-engineered monoclonal antibody (mAb) able to neutralize in vitro all current SARS-CoV-2 variants of concern (VoCs) including the omicron variant even if with significantly reduced potency. Here we evaluated data obtained from the first 30 days of a phase 1 clinical study (EudraCT N.: 2020-005469-15 and ClinicalTrials.gov Identifier: NCT04932850). The primary endpoint evaluated the percentage of severe adverse events. Secondary endpoints evaluated pharmacokinetic and serum neutralization titers. A single dose administration of MAD0004J08 via intramuscular (i.m.) route is safe and well tolerated, resulting in rapid serum distribution and sera neutralizing titers higher than COVID-19 convalescent and vaccinated subjects. A single dose administration of MAD0004J08 is also sufficient to effectively neutralize major SARS-CoV-2 variants of concern (alpha, beta, gamma and delta). MAD0004J08 can be a major advancement in the prophylaxis and clinical management of COVID-19.

Challenges in early clinical development of adjuvanted vaccines.

A three-step approach to the early development of adjuvanted vaccine candidates is proposed, the goal of which is to allow ample space for exploratory and hypothesis-generating human experiments and to select dose(s) and dosing schedule(s) to bring into full development. Although the proposed approach is more extensive than the traditional early development program, the authors suggest that by addressing key questions upfront the overall time, size and cost of development will be reduced and the probability of public health advancement enhanced. The immunogenicity end-points chosen for early development should be critically selected: an established immunological parameter with a well characterized assay should be selected as primary end-point for dose and schedule finding; exploratory information-rich end-points should be limited in number and based on pre-defined hypothesis generating plans, including system biology and pathway analyses. Building a pharmacodynamic profile is an important aspect of early development: to this end, multiple early (within 24h) and late (up to one year) sampling is necessary, which can be accomplished by sampling subgroups of subjects at different time points. In most cases the final target population, even if vulnerable, should be considered for inclusion in early development. In order to obtain the multiple formulations necessary for the dose and schedule finding, "bed-side mixing" of various components of the vaccine is often necessary: this is a complex and underestimated area that deserves serious research and logistical support.

Safety and immunogenicity of an MF59-adjuvanted A/H1N1 pandemic influenza vaccine in children from three to seventeen years of age.

OBJECTIVES: This study was designed to identify the optimal dose of an MF59-adjuvanted, monovalent, A/H1N1 influenza vaccine in healthy paediatric subjects. METHODS: Subjects aged 3-8 years (n=194) and 9-17 years (n=160) were randomized to receive two primary doses of A/H1N1 vaccine containing either 3.75 µg antigen with half a standard dose of MF59 adjuvant, 7.5 µg antigen with a full dose of MF59, or (children 3-8 years only), a non-adjuvanted 15 µg formulation. A booster dose of MF59-adjuvanted seasonal influenza vaccine including homologous A/H1N1 strain was given one year after priming. Immunogenicity was assessed by haemagglutination inhibition (HI) and microneutralization assays. Vaccine safety was assessed throughout the study (up to 18 months). RESULTS: A single priming dose of either MF59-adjuvanted formulation was sufficient to meet the European licensure criteria for pandemic influenza vaccines (HI titres ≥1:40>70%; seroconversion>40%; and GMR>2.5). Two non-adjuvanted vaccine doses were required to meet the same licensure criteria. After first and second doses, percentage of subjects with HI titres ≥1:40 were between 97% and 100% in the adjuvanted vaccine groups compared with 68% and 91% in the non-adjuvanted group, respectively. Postvaccination seroconversion rates ranged from 91% to 98% in adjuvanted groups and were 68% (first dose) and 98% (second dose) in the non-adjuvanted group. HI titres ≥1:330 after primary doses were achieved in 69% to 90% in adjuvanted groups compared with 41% in the non-adjuvanted group. Long-term antibody persistence after priming and a robust antibody response to booster immunization were observed in all vaccination groups. All A/H1N1 vaccine formulations were generally well tolerated. No vaccine-related serious adverse events occurred, and no subjects were withdrawn from the study due to an adverse event. CONCLUSIONS: An MF59-adjuvanted influenza vaccine containing 3.75 µg of A/H1N1 antigen was well tolerated and sufficiently immunogenic to meet all the European licensure criteria after a single dose in healthy children 3-17 years old.

Immunogenicity and tolerability of an MF59-adjuvanted, egg-derived, A/H1N1 pandemic influenza vaccine in children 6-35 months of age.

BACKGROUND: Vaccines against pandemic A/H1N1 influenza should provide protective immunity in children, because they are at greater risk of disease than adults. This study was conducted to identify the optimal dose of an MF59®-adjuvanted, egg-derived, A/H1N1 influenza vaccine for young children. METHODS: Children 6-11 months (N = 144) and 12-35 months (N = 186) of age received vaccine formulations containing either 3.75 µg antigen with half the standard dose of MF59 or 7.5 µg antigen with a standard dose of MF59, or a nonadjuvanted formulation containing 15 µg antigen (children 12-35 months only). Participants were given 2 primary vaccine doses 3 weeks apart, followed by 1 booster dose of MF59-adjuvanted seasonal influenza vaccine 1 year later. Immunogenicity was assessed by hemagglutination inhibition and microneutralization assays. RESULTS: All vaccine formulations were highly immunogenic and met all 3 European licensure criteria after 2 doses. MF59-adjuvanted vaccines met all licensure criteria after 1 dose in both age cohorts, while nonadjuvanted vaccine did not meet all criteria after 1 dose in children 12-35 months. A single booster dose was highly immunogenic, and stable antibody persistence was observed in response to all vaccines. All vaccines were well tolerated. CONCLUSIONS: In this study, a single dose of 3.75 µg antigen with half the standard dose of MF59 was shown to be optimal, providing adequate levels of immediate and long-term antibodies in pediatric subjects 6-35 months of age. These data demonstrated that MF59 adjuvant allowed for reduced antigen content and promoted significant long-term antibody persistence in children, with a satisfactory safety profile.

A cell culture-derived MF59-adjuvanted pandemic A/H7N9 vaccine is immunogenic in adults.

A potentially deadly A/H7N9 avian-origin influenza virus is currently the cause of an ongoing outbreak in China. Preparedness plans have thus been initiated to preempt the spread of this virus, which appears to have substantial pandemic potential. To effectively prevent a pandemic from unfolding, rapid production of an immunogenic vaccine with an acceptable safety profile is critical. Given the significance to public health, we are reporting immunogenicity and safety results from a phase 1 study in healthy adults administered one of four inactivated A/H7N9 vaccine formulations. Three formulations contained increasing quantities of antigen and of an oil-in-water adjuvant, MF59, and one formulation contained only the maximum dose of antigen without adjuvant. All vaccine formulations were derived using a synthetic virus seed technology in combination with a cell culture approach; together, these techniques have been shown to expedite vaccine production compared to conventional methods. Higher responses were seen with the MF59-adjuvanted versus the nonadjuvanted A/H7N9 vaccine, with significant and potentially protective immune responses after two doses in most subjects with no preexisting immunity to the H7N9 virus. Further, despite increased injection site pain and other mild effects with MF59, all formulations were well tolerated. These encouraging immunogenicity and safety data on the A/H7N9 vaccine provide a strong rationale for further clinical development. By also using synthetic seed/cell culture technology, we are now one step closer to being able to rapidly and reliably respond to a potential H7N9 pandemic using a clinically tested A/H7N9 vaccine.

A dose-ranging study in older adults to compare the safety and immunogenicity profiles of MF59®-adjuvanted and non-adjuvanted seasonal influenza vaccines following intradermal and intramuscular administration.

UNLABELLED: Strategies to optimize responses to seasonal influenza vaccination in older adults include the use of adjuvants, higher antigen doses, and intradermal delivery. In this study adults aged ≥65 years (n = 450) received a single dose of 1 of 2 non-adjuvanted trivalent influenza vaccine (TIV) formulations administered intradermally (ID), both containing 6 µg of A/H1N1 and B, differing in A/H3N2 content (6 µg or 12 µg), or a single dose of 1 of 8 TIV formulations administered intramuscularly (IM) all containing 15 µg of A/H1N1 and B, differing in A/H3N2 hemagglutinin (HA) content (15 µg or 30 µg) and/or in MF59(®) adjuvant content (0%, 25%, 50%, or 100% of the standard dose). This paper focuses on the comparisons of low-dose non-adjuvanted ID, full-dose non-adjuvanted IM and full-dose MF59-adjuvanted IM formulations (n = 270). At day 22 post-vaccination, at least one European licensure immunogenicity criterion was met by all groups against all 3 strains; however, all three criteria were met against all 3 vaccine strains by the low-dose non-adjuvanted ID and the full-dose MF59-adjuvanted IM groups only. The full-dose MF59-adjuvanted IM group elicited significantly higher immune response vs. the low-dose non-adjuvanted ID formulations for most comparisons. The full-dose MF59 adjuvanted IM groups were associated with increased pain at the site of injection (P<0.01) compared to the ID groups, and the low-dose non-adjuvanted ID groups were associated with increased erythema, induration, and swelling at the injection site (P<0.0001) and unsolicited AEs compared with the IM groups. There were no differences between IM and ID groups in the frequencies of subjects experiencing solicited systemic reactions. Overall, while MF59 adjuvantation increased pain at the site of injection, and intradermal delivery increased unsolicited adverse events, erythema, induration, and swelling at the injection site, both strategies of vaccination strongly enhanced the immunogenicity of seasonal influenza vaccine in older adults compared with conventional non-adjuvanted intramuscular delivery. TRIAL REGISTRATION: http://www.clinicaltrials.gov: NCT00848848.

Safety of MF59-adjuvanted influenza vaccination in the elderly: results of a comparative study of MF59-adjuvanted vaccine versus nonadjuvanted influenza vaccine in northern Italy.

MF59-adjuvanted trivalent influenza vaccine (Novartis Vaccines and Diagnostics, Siena, Italy) has been shown to be more effective than nonadjuvanted vaccine in the elderly population. Here we present results from a large-scale, observational, noninterventional, prospective postlicensure study that evaluated the safety of MF59-adjuvanted vaccine in elderly subjects aged 65 years or more. The study was performed in 5 northern Italian health districts during the 2006-2007, 2007-2008, and 2008-2009 influenza seasons. The choice of vaccine-either adjuvanted vaccine or a nonadjuvanted influenza vaccine-was determined by individual providers on the basis of local influenza vaccination policy. Hospitalizations for potential adverse events of special interest (AESIs) were identified from hospital databases and then reviewed against recognized case definitions to identify confirmed cases of AESI. Cumulative incidences were calculated for AESIs in predefined biologically plausible time windows, as well as in a 6-month window following vaccination. During the 3-year study period, 170,988 vaccine doses were administered to a total of 107,661 persons. Despite the large study size, cases of AESI resulting in hospitalization were rare, and risks of AESI were similar in both the MF59-adjuvanted and nonadjuvanted vaccination groups. In conclusion, similar safety profiles were observed for both nonadjuvanted and MF59-adjuvanted seasonal influenza vaccines in elderly recipients.

Aflunov®: a vaccine tailored for pre-pandemic and pandemic approaches against influenza.

INTRODUCTION: Aflunov is an egg-derived, subunit vaccine from Novartis Vaccines and Diagnostics containing 7.5 µg of hemagglutinin (HA) from the avian A/H5N1 virus and the oil-in-water adjuvant MF59. AREAS COVERED: Aflunov behaves as a pre-pandemic vaccine. It has a good safety profile at all ages. At all ages, it induces high and persisting antibody titers and activation of HA-specific Th0/Th1 CD4(+) T cells, the levels of which correlate with the neutralizing antibody titers after a booster dose 6 months later. Aflunov triggers strong immunological memory, which persists for at least 6 - 8 years and can be rapidly boosted with a heterovariant vaccine strain, inducing very high neutralizing antibody titers within one week. These antibodies broadly and strongly cross-react with drifted H5N1 virus strains from various clades. Finally, the MF59 changes the pattern of HA recognition by antibodies that react with the HA1 more than with the HA2 region. EXPERT OPINION: The available data show that Aflunov is a pre-pandemic vaccine suitable not only for stockpiling in case of a pandemic, but also before a pandemic is declared, with the ultimate objective of preventing the onset of an influenza pandemic.

Safety of MF59-adjuvanted A/H1N1 influenza vaccine in pregnancy: a comparative cohort study.

OBJECTIVE: The 2009-2010 A/H1N1 pandemic provided a unique setting to study the safety of MF59-adjuvanted vaccination in pregnancy. STUDY DESIGN: This was an observational cohort study of the safety of an MF59-adjuvanted A/H1N1 vaccine (Focetria) conducted among 4508 pregnant women (2295 vaccinated vs 2213 unvaccinated), with 3 month follow-up of neonates. RESULTS: No maternal deaths or abortions occurred among the vaccinated women. No differences between the vaccinated and unvaccinated cohorts were observed for gestational diabetes, preeclampsia, stillbirth, low birthweight, neonatal deaths, or congenital malformations. The risk of premature birth was significantly decreased among the vaccinated women (adjusted proportional hazard, 0.69; 95% confidence interval, 0.51-0.92). No differences were observed in rates of congenital malformations after vaccination in the first (2.1%), second (2.7%), or third (2.1%) trimesters. CONCLUSION: There was no evidence of a safety risk for MF59-adjuvanted A/H1N1 vaccination in pregnant women; protection was observed against premature birth.

Superior immunogenicity of seasonal influenza vaccines containing full dose of MF59 (®) adjuvant: results from a dose-finding clinical trial in older adults.

BACKGROUND: MF59-adjuvanted influenza vaccines have superior immunogenicity in older adults compared with non-adjuvanted vaccines. We assessed whether changing formulation (i.e., increasing H3N2 antigen or decreasing the quantity of adjuvant) of the licensed, MF59-adjuvanted trivalent influenza subunit vaccine Fluad (®) (Novartis Vaccines and Diagnostics) improves the risk-benefit profile in vaccinees aged ≥ 65 years. RESULTS: A significant dose-response relationship was observed between antibody levels and MF59 dose; full dose formulations elicited the strongest immune responses, meeting immunogenicity licensure criteria by Day 8. Doubling H3N2 antigen content did not increase the response to this antigen. Increased frequency of circulating CD4+ T-cells specific for vaccine antigens were detected by Day 8; magnitude and functional profile of the CD4+ T-cell response was comparable across the different vaccination groups. Mild to moderate solicited local reactions were more common with vaccines formulated with higher doses of MF59 (®) , but there were no MF59- or antigen dose-related increase in the frequency of solicited systemic reactions or unsolicited adverse events and serious adverse events. METHODS: We report on 357 subjects who received one of eight intramuscular vaccine formulations. Hemagglutination-inhibiting antibodies were assayed on Days 1, 8 and 22; magnitude and functional profile of CD4+ T-cell responses to vaccine antigens were assessed in subsets. Solicited adverse reactions were reported via diary cards for seven days after vaccination and spontaneous adverse events were monitored throughout the study. CONCLUSION: This study confirms that the current formulation is the optimal one for MF59-adjuvanted influenza vaccine for use in older adults.

Hemagglutination inhibition antibody titers as a correlate of protection for inactivated influenza vaccines in children.

INTRODUCTION: The hemagglutination inhibition (HI) titer of 1:40, which has been recognized as an immunologic correlate corresponding to a 50% reduction in the risk of contracting influenza, is based on studies in adults. Neither seasonal nor challenge-based correlates have been evaluated in children. METHODS: A total of 4707 influenza vaccine-naive healthy children 6 to 72 months old were randomized in a ratio of 2:2:1 to receive 2 doses of MF-59-adjuvanted influenza vaccine (Novartis Vaccines), trivalent inactivated influenza vaccine subunit (trivalent inactivated influenza vaccine control, GSK), or a saline placebo during the 2007 to 2008 and 2008 to 2009 influenza seasons. The second dose was given 30 days after dose 1. Clinical influenza-like illnesses cases identified by active surveillance were confirmed by reverse transcription polymerase chain reaction testing for influenza. Vaccine immunogenicity 50 days after dose 1 was evaluated in a subset of 777 children. RESULTS: Immunogenicity and efficacy results for H3N2 were evaluated against the Prentice criteria, which confirmed that the immunogenicity results warranted estimation of an immunologic correlate. We then used the Dunning model fitting the H3N2 antibody titers at day 50 and the influenza cases observed in the immunogenicity subset to estimate a correlate of protection. This analysis revealed that a cutoff HI titer of 1:110 was associated with the conventional 50% clinical protection rate against infection during the entire season, and titers of 1:215, 1:330, and 1:629 predicated protection rates of 70%, 80%, and 90%, respectively. The conventional adult HI titer of 1:40 was only associated with 22% protection. CONCLUSIONS: The use of the 1:40 HI adult correlate of protection is not appropriate when evaluating influenza vaccines in children. Although a cutoff of 1:110 may be used to predict the conventional 50% clinical protection rate, a titer of 1:330 would predict an 80% protective level, which would seem to be more desirable from a public health perspective.

Trivalent and quadrivalent MF59(®)-adjuvanted influenza vaccine in young children: a dose- and schedule-finding study.

Young children are at increased risk for influenza infections and related complications. The protection offered to children by conventional trivalent inactivated influenza vaccines (TIV) is suboptimal, due to poor immunogenicity and a higher exposure to infection and complications in this age group, particularly from influenza B strains. In this dose-ranging, factorial design trial, we report the safety and immunogenicity of different combinations of adjuvanted (ATIV) and non-adjuvanted trivalent (TIV) and quadrivalent (QIV) influenza vaccines in 480 healthy children 6 to <36 months of age. The results show that the second B strain added to TIV was immunogenic and did not affect immunogenicity of the other strains. The addition of the MF59(®) adjuvant promoted robust immune responses with notable elevations in antibodies observed even after one dose. A dose-response relationship was observed between the antibody response and MF59 adjuvant. No patterns in safety and tolerability emerged with different adjuvant and antigen doses nor with the addition of a second B strain. MF59-adjuvanted QIV offers potential advantages to young children.

Explorations of clinical trials and pharmacovigilance databases of MF59®-adjuvanted influenza vaccines for associated cases of narcolepsy.

BACKGROUND: A potential association between the new onset of narcolepsy accompanied by cataplexy - a putative autoimmune disorder, and vaccination with an AS03-adjuvanted A(H1N1) pandemic influenza vaccine is under investigation. We sought cases of narcolepsy from the pharmacovigilance database of a pandemic vaccine adjuvanted with another emulsion adjuvant, MF59(®), and a pooled clinical trials database of MF59-adjuvanted and non-adjuvanted influenza vaccine recipients. METHODS: Using 6 narrowly restrictive and 24 broad sleep disturbance-related MedDRA preferred search terms (PT), we analysed spontaneous adverse events (AEs) reports received through July 31, 2010 and adjudicated suspected cases with onset 1 week-3 months after vaccination, against standardized clinical criteria defining narcolepsy. A pooled clinical trials database of 115 trials comprising 79,004 subjects receiving various MF59-adjuvanted and non-adjuvanted influenza vaccines in controlled and uncontrolled trials was analysed for cases with a narrow PT that had onset 1 week after vaccination. RESULTS: Five thousand three hundred and five spontaneous AE reports were received from an estimated 23.26 million MF59-adjuvanted pandemic vaccine doses that had been administered. No case meeting the clinical definition of narcolepsy was discovered. In the pooled database of controlled clinical trials, no cases were discovered using the narrow PT, and rates and adjusted odds ratio for broad search terms for all temporal windows showed no significant difference between subjects receiving MF59-adjuvanted or non-adjuvanted vaccine. CONCLUSIONS: No case of narcolepsy and no evidence of an increased risk of sleep-related AEs were discovered in recipients of MF59-adjuvanted A(H1N1) pandemic and other MF59-adjuvanted influenza vaccine.

Assessment of the safety, tolerability and kinetics of the immune response to A/H1N1v vaccine formulations with and without adjuvant in healthy pediatric subjects from 3 through 17 years of age.

BACKGROUND: The recent global A/H1N1v pandemic led to major efforts to develop effective vaccines against the novel virus, while global demand and limited production capacity focused attention on dose sparing and schedules. METHODS: An open-label phase III study of immunogenicity and safety of novel A/H1N1v vaccines included 392 Costa Rican children in two pediatric cohorts (3-8 and 9-17 years). They received two doses, of either an MF59®-adjuvanted formulation containing 7.5 µg antigen or non-adjuvanted formulations containing 15 or 30 µg antigen, three weeks apart. Immunogenicity was assessed as hemagglutination inhibition (HI) titers using the CBER licensure criteria. RESULTS: All three vaccines elicited immune responses in 9-17 year-olds meeting CBER criteria three weeks after one dose; responses were not enhanced by second dose. In 3-8 year-olds only the adjuvanted vaccine met the CBER criteria after one dose, but all three vaccines met criteria after second dose. All vaccines were well tolerated; no related Serious Adverse Events (SAE) and few severe solicited reactions were reported. MF59-adjuvanted vaccine was associated with more reports of injection site pain and tenderness and overall systemic solicited reactions, most notably in older subjects, all of which decreased after the second dose. CONCLUSION: One dose of non-adjuvanted A/H1N1v vaccine is adequate in 9-17 year-olds, but younger children require either one dose of MF59-adjuvanted vaccine or two doses of non-adjuvanted vaccine to achieve protective titers. Enhanced immunogenicity with MF59 is associated with a small increase in reactogenicity, but no safety issues.

Safety of MF59-adjuvanted versus non-adjuvanted influenza vaccines in children and adolescents: an integrated analysis.

We reviewed the safety of MF59-adjuvanted versus non-adjuvanted influenza vaccines in children and adolescents (aged 6 months-18 years) in an integrated analysis of all pediatric trials evaluating MF59-containing influenza vaccines completed to date (5 trials). In the MF59-adjuvanted group (n=1181) versus the non-adjuvanted group (n=545) there was no increase in the incidence of unsolicited adverse events and serious adverse events. As expected, solicited local or systemic reactions occurred more frequently in MF59-adjuvanted subjects; however, a majority of reactions were mild and transient. These data support the safety of MF59-adjuvanted influenza vaccines in the pediatric population.

MF59-adjuvanted versus non-adjuvanted influenza vaccines: integrated analysis from a large safety database.

BACKGROUND: Adding adjuvants such as MF59((R)) to influenza vaccines can enhance the immune response. This analysis evaluated the safety profile of MF59-adjuvanted [(+)MF59] compared with non-adjuvanted [(-)MF59] vaccines in a large clinical database. METHODS: Safety data were pooled from 64 clinical trials involving (+)MF59 seasonal and pandemic influenza vaccines. Safety outcomes were analysed in the overall population and in subjects aged > or =65 years, in all clinical trials and in controlled trials only. FINDINGS: Data from 20,447 (+)MF59 and 7526 (-)MF59 subjects were analysed. Overall, (+)MF59 subjects had lower risks than (-)MF59 subjects of experiencing any unsolicited adverse event (AE) (26.8% vs 39.2%; adjusted risk ratio [ARR] 0.65; 95% CI 0.60-0.70), cardiovascular AEs (1.9% vs 5.6%; ARR 0.44; 95% CI 0.35-0.55), new onset chronic diseases (1.3% vs 1.9%; ARR 0.71; 95% CI 0.57-0.87) and death (0.8% vs 1.2%; ARR 0.67; 95% CI 0.51-0.87). Few AEs of potential autoimmune origin were reported: 0.71 and 0.67 per 1000 with (+)MF59 and (-)MF59, respectively. As expected, (+)MF59 subjects had a higher risk of solicited local or systemic reactions within 3 days of vaccination (58.5% vs 46.9%, weighted RR 1.34; 95% CI 1.28-1.40). Safety outcomes were consistent between total and elderly populations, and between all trials and controlled trials, although statistical significance was lost for some of the outcomes in the subgroups. INTERPRETATION: This large-scale analysis supports the good safety profile of (+)MF59 seasonal and pandemic influenza vaccines and suggests a clinical benefit over (-)MF59 influenza vaccines.

Formoterol, 24 microg bid, and serious asthma exacerbations: similar rates compared with formoterol, 12 microg bid, with and without extra doses taken on demand, and placebo.

STUDY OBJECTIVES: The primary objective was to determine whether high-dose formoterol, 24 mug bid, was associated with more asthma exacerbations compared with lower formoterol doses in patients with stable persistent asthma. Serious asthma exacerbations (life threatening or requiring hospitalization) were the primary end point. Secondary end points included significant exacerbations requiring systemic corticosteroids, all exacerbations, and changes in FEV1. DESIGN: In a multicenter, placebo-controlled, parallel-group study, patients were randomized to 16 weeks of treatment with formoterol, 24 microg bid; formoterol, 12 microg bid, with up to two additional 12-microg doses daily on demand for worsening symptoms (12 microg bid plus on demand); formoterol, 12 microg bid; or placebo. The formoterol 12-microg-bid plus on-demand regimen was administered open label, while the other three regimens were double blind. SETTING: Outpatient clinics. PATIENTS: A total of 2,085 patients aged > or = 12 years with stable, persistent asthma were enrolled and treated; 65% (n = 1,347) received regular concomitant antiinflammatory therapy during the study. MEASUREMENTS AND RESULTS: Nine patients had respiratory-related serious adverse events (SAEs) requiring hospitalization: two patients (0.4%) in the 24-microg-bid group; one patient (0.2%) in the 12-microg-bid plus on-demand group; five patients (0.9%) in the 12-microg-bid group; and one patient (0.2%) in the placebo group. All of these events were asthma related, except for two SAEs in the 12-microg-bid group that were later considered not to be asthma related by independent reviewers who were not associated with the conduct of the study. The proportions of patients with significant asthma exacerbations (requiring systemic corticosteroids) were similar in the 24-microg-bid group (6.3%, 33 of 527 patients), 12-microg-bid group (5.9%, 31 of 527 patients) and placebo group (8.8%, 45 of 514 patients) and lower in the 12-microg-bid plus on-demand group (4.4%, 23 of 517 patients; p = 0.0057 vs placebo). All treatments were well tolerated. All formoterol treatment regimens had a significant effect on FEV1 measured 2 h after dose during the study (p < 0.0001 vs placebo); and on predose trough FEV1 measured at all visits after baseline (p < 0.002 vs placebo). CONCLUSIONS: Treatment with formoterol, 24 microg bid, was not associated with an increase in serious asthma exacerbations compared with the lower formoterol doses or placebo.

Effects of formoterol and salmeterol on resting inspiratory capacity in COPD patients with poor FEV(1) reversibility.

BACKGROUND: Recent studies suggest that inspiratory capacity (IC) measured at rest can be used to predict improvements in dyspnea and exercise tolerance in chronic obstructive pulmonary disease (COPD) patients. In this study we compared the effect of formoterol (Foradil, Aerolizer) and salmeterol (Serevent, Diskus) in terms of IC in patients with COPD. METHODS: This was a multicentre, randomized, placebo-controlled, single-dose, double-dummy, crossover study conducted in five secondary care centres in four European countries. A total of 47 patients with Stage II and III COPD, as defined by ATS criteria, with an increase in forced expiratory volume in 1s (FEV(1)) of

Inspiratory flow rates and volumes with the Aerolizer dry powder inhaler in asthmatic children and adults.

OBJECTIVE: To assess the peak inspiratory flow rate (PIFR) and forced inspiratory vital capacity (FIVC) through the formoterol (Foradil*) Aerolizer* in patients with mild, moderate and severe asthma. RESEARCH DESIGN AND METHODS: PIFR and FIVC were assessed in 33 adults and 32 children using a spirometer alone (baseline), a spirometer with an adaptor, and a spirometer with an adaptor and the Aerolizer inhaler (placebo loaded). RESULTS: Of adult patients using the Aerolizer inhaler, 73% had PIFR values of >100 l/min and 91% had values of >60 l/min. PIFR in adults was reduced from a mean baseline of 283 l/min to 118 l/min through the loaded Aerolizer inhaler. Similarly, 75% of children using the Aerolizer inhaler had PIFR values >80 l/min and 91% had values of > 60 l/min. The mean PIFR in children was reduced from a baseline of 154 l/min to 100 l/min through the loaded Aerolizer inhaler. Only small mean decreases from baseline were observed in FIVC through the loaded Aerolizer inhaler: 8.4% in adults and 3.8% in children. FIVC values of > 2.0 litre were achieved in 82% of adults, and 81% of children achieved FIVC values of >1.5 litre. CONCLUSIONS: This study, albeit in a relatively small patient population, suggests that most children and adults with asthma can generate PIFRs of > 60 l/min and FIVCs of > 1.5 litre through the Aerolizer inhaler regardless of their disease severity. Such findings compare extremely favourably with other dry powder inhalers.

Tolerability of retreatment with omalizumab, a recombinant humanized monoclonal anti-IgE antibody, during a second ragweed pollen season in patients with seasonal allergic rhinitis.

Two randomized, placebo-controlled, double-blind studies have shown clinical benefit with omalizumab (Xolair), a recombinant humanized monoclonal anti-immunoglobulin E (IgE) antibody, at a dose of 300 mg every 3 or 4 weeks in patients with seasonal allergic rhinitis. The present open-label, 12-week study was designed to assess the safety and tolerability of retreatment with omalizumab in 287 patients previously treated with this agent in one of the latter studies. Omalizumab, 300 mg, was administered subcutaneously every 4 weeks (three injections) to patients with IgE levels < or = 150 IU/mL (n = 182) and every 3 weeks (four injections) to patients with IgE levels > 150 IU/mL (n = 105) at screening before retreatment. Reported adverse events were monitored and blood samples were analyzed for laboratory safety (hematology and serum chemistry) and IgE levels. Urinalysis also was completed as part of the laboratory safety evaluation. The overall incidence and pattern of adverse events were similar to those reported in the primary study. There were no severe or serious adverse events related to omalizumab treatment and no anti-omalizumab antibodies were detected in any patient. Two patients withdrew from treatment because of adverse events (skin rash and nausea; facial erythema and edema) related to study treatment. Free IgE levels decreased to the levels associated with symptom reduction in the core study. In summary, retreatment during a second pollen season with omalizumab, 300 mg every 3 or 4 weeks, was well tolerated and was not associated with any significant immunologic reactions.