FormalPara Key Summary Points

Why carry out this study?

Invasive meningococcal disease (IMD) is uncommon, severe and life-threatening.

Most IMD cases in Germany are due to serogroup B, preventable with the four-component meningococcal serogroup B vaccine (4CMenB).

The public health and economic impact of introducing a universal infant 4CMenB immunisation program was modelled to inform decision-making in Germany.

What was learned from the study?

4CMenB could prevent 3154 (3303) cases, 291 (304) deaths and 1370 (1435) sequelae due to serogroup B IMD (all serogroups IMD), respectively, over 100 years.

The cost per quality-adjusted life year gained was around €189,000 from a societal perspective.

Introduction

Neisseria meningitidis (Nm) bacteria are present in the nasopharynx of around 10% of the adult population and up to 25% of adolescents, without causing symptoms [1, 2]. However, if the pathogen penetrates the mucosal barrier in the absence of type-specific immunity, severe and life-threatening invasive meningococcal disease (IMD) may occur. IMD is an uncommon infectious disease with the highest incidence typically seen in infants. IMD has an unpredictable incidence, risk of outbreaks and occasional epidemics, with Nm serogroups varying by region and over time [3]. In 2019, around 256 cases of IMD were reported in Germany, representing an incidence of 0.3 IMD cases per 100,000 persons. The highest incidence (IMD cases per 100,000 persons) was seen in infants (2.8), 1-year-olds (1.9) and young adults 15–19 and 20–24 years of age (0.5 and 0.6) [4]. Patients typically presented with meningitis (60% of cases), septicaemia (75% of cases) or both (35% of cases) [4]. Patients with IMD may die within hours after symptoms appear, even if they are rapidly treated and hospitalised. At discharge from hospital, up to 51.6% of infant survivors [5] (and around 30% of survivors overall [6]) will have one or more sequelae that can be lifelong and of varying severity, including a range of physical, neurological and psychological or behavioural conditions (e.g. physical disability due to limb amputations, or hearing loss) [7]. Thus, IMD can have a lifelong impact on patients, affecting their quality of life, education and ability to work, as well as an impact on the quality of life and productivity of their family, especially if patients with IMD suffer from severe sequelae with the need for lifelong caregiving [7].

There are five Nm serogroups that cause the most IMD in Europe: serogroups A, B, C, W and Y. Since the introduction of universal mass vaccination (UMV) to control Nm serogroup C (MenC) IMD in Europe (e.g. introduced in 2006 in Germany for children from 12 months of age [8]), Nm serogroup B (MenB) became the predominant cause of IMD. In 2019, 61% of all notified IMD cases in Germany were caused by MenB [4]. The four-component MenB vaccine (4CMenB), licensed in the European Union in 2013, is the only serogroup B vaccine for infants. In Europe, 4CMenB infant vaccination is already included as UMV in the United Kingdom (UK), Ireland, Portugal, Czech Republic, Lithuania, Malta, Italy (including San Marino), Andorra [9] as well as Austria [10] and recently France [11]. After the first 3 years of 4CMenB UMV introduction in the UK in 2015, and based on the high vaccination uptake achieved (i.e. around 93% and 88% of children receiving two doses by 12 months of age and three doses by 24 months of age), there was a 75% reduction in observed incidence in the vaccine-eligible age group [12].

In Germany, the Standing Committee on Vaccination (Ständige Impfkommission, STIKO) is the independent National Immunization Technical Advisory Group (NITAG) that recommends vaccines for inclusion in the national vaccination schedule with subsequent mandatory reimbursement by the statutory health insurance. Decision-making by STIKO is usually supported by epidemiologic and economic modelling studies. A previous health economic analysis of childhood 4CMenB UMV in Germany, by Christensen et al. [13], estimated incremental cost-effectiveness ratios (ICERs) of over €1.9 million per quality-adjusted life year (QALY) gained excluding indirect effects. The STIKO recommended 4CMenB vaccination since 2015 for certain risk groups and, to prevent outbreaks, for post-exposure vaccination of unvaccinated household contacts of a patient with IMD [14] and decided not to include 4CMenB infant vaccination in the national immunization schedule during their reassessment in 2018 [15] due to further evidence needed (e.g. on vaccine effectiveness, safety and carriage protection). Since 2018, new evidence has become available filling in these and other evidence gaps, such as the burden and costs of IMD in Germany. A recent study analysing the clinical and economic burden of IMD in Germany found that hospitalised IMD cases had a risk of mortality of 5.5% in the first year after IMD and 24% of survivors had some form of sequelae (e.g. chronic renal failure, epilepsy, blindness and learning disabilities). While this analysis did not include any long-term costs or indirect costs, IMD cases were found to have significantly higher initial hospitalisation costs and rates of hospitalisation during the follow-up period versus matched controls [16]. A cost-of-illness model estimated MenB IMD lifetime costs in Germany and predicted a significant direct cost per patient of €54,300, primarily due to sequelae management costs. Total costs per case were €57,100 or €171,000, using the friction-cost approach (FCA) and human capital approach (HCA) for indirect costs, respectively. Based on a hypothetical cohort of around 340 cases in Germany, lifetime societal costs were around €20 million (FCA) to nearly €60 million (HCA) [17].

Based on new evidence available on the 4CMenB vaccine, as well as the humanistic and economic burden of IMD, the objective of this analysis was to reassess the potential public health impact and cost-effectiveness of introducing infant 4CMenB UMV in Germany.

Methods

A dynamic transmission-based cost-effectiveness model (DyCE) [18] was adapted to the German setting to compare the impact of 4CMenB infant UMV (at 2, 4 and 12 months of age) versus no vaccination on the humanistic and economic burden due to MenB IMD and all IMD. To exclude the potential impact of the MenB vaccination recommendation for risk groups from September 2015 [14, 19] on the burden of MenB IMD/IMD, the model analysis was started in 2015, hence, starting in a setting assuming no vaccination. The model used Nm serogroup-specific input data wherever available, otherwise IMD data were applied (Supplemental Table S1).

Model Structure

The model (Supplemental Fig. S1) has been previously published for England and described in detail (Beck et al. [18]). Briefly, the model includes a dynamic transmission component, adapted with German demographic data, IMD incidence and data on the contacts from the POLYMOD study for Germany [20], to generate age-specific IMD cases in the arms with and without 4CMenB routine vaccination. The model can calculate direct and indirect effects of vaccination, such as 4CMenB cross-protection against other non-MenB IMD (i.e. serogroups W and Y IMD), and the potential effects on reducing Nm carriage and therefore transmission, resulting in herd protection. With a time horizon of 100 years, the model’s economic decision-tree component determines the health states associated with each IMD case over their lifetime. The model uses probabilities of death due to IMD in the acute phase, of surviving without sequelae, or of surviving with one or more of a range of up to 16 possible sequelae based on MenB IMD observational studies [6, 21] (multiple sequelae can occur independently of each other). The costs and QALYs associated with each health state are applied to MenB (all IMD) cases in each arm of the decision tree, to assess the ICER of 4CMenB infant UMV versus no vaccination.

Quality of Life, Demographic and Economic Inputs

QALYs were calculated for non-fatal cases and premature deaths during the acute phase of IMD and for sequelae, using the utility weights listed in Supplemental Table S1 and populations norms for Germany [22]. The life expectancy at age of IMD onset taken from German lifetables [23] was used to calculate the overall QALY loss per case. Health spillover effects (i.e. QALY losses beyond the patient for the family/caregivers and formal long-term caregivers [24, 25] as well as a bereavement factor [26, 27]) were included in the QALY losses due to IMD (see Supplemental Table S1).

A bottom-up age-specific IMD costing approach for Germany was used and is described in Scholz et al. [17]. In summary, costs in the acute phase included hospitalisation, public health response (e.g. contact tracing and chemoprophylaxis) and indirect costs due to premature mortality and productivity loss in IMD cases. Following the acute phase, direct costs for life-long sequelae included inpatient and outpatient care, rehabilitation, special education and long-term care (calculated for year 1 and for subsequent years). Indirect costs included lost productivity in IMD cases of working age (15–65 years) and in one parent of childhood IMD cases [17].

Vaccine Inputs

Clinical trial immunogenicity data are now confirmed by real-world evidence showing 79% vaccine effectiveness against MenB IMD in fully vaccinated people (after two or more doses according to age), from a recently published case–control study in Portugal [28]. 4CMenB uptake by the age of 12 months increased in Portugal from around 33% in the 2015 birth cohort to 57% in 2018, and there were sufficient numbers of MenB IMD cases during the case–control study, in particular among controls, to provide a robust estimate of vaccine effectiveness reaching statistical significance [28]. At the time of the study, a 3 + 1 schedule was used in infants, with a 2 + 1 schedule recommended later in January 2018 by the Portuguese Society of Paediatrics [29]; however, non-inferiority was demonstrated for immunogenicity of the 2 + 1 versus 3 + 1 schedule [30] and therefore the model uses these vaccine effectiveness values. This model was previously used in the UK [18], and the impact of 4CMenB using the Portuguese vaccine effectiveness estimates provided comparable vaccine impact results to those observed from real-world data after 3 years of routine 4CMenB infant vaccination [12]. Model vaccine effectiveness against MenB IMD was assumed to be 0% after the first dose (conservative assumption) and 79% after the second and booster doses. Vaccine uptake for the first, second and booster dose was assumed to be 92%, 91% and 71%, respectively, based on applying a 5%-point reduction to pneumococcal vaccination coverage rates in Germany [31]. Waning was conservatively modelled using the estimated mean duration of protection of 33 months after the second dose and 38 months after the booster dose [30, 32].

The 4CMenB vaccine has shown potent serum bactericidal antibody activity against serogroups C, W and Y, with 68% of Nm serogroup W (MenW) strains and 87% of Nm serogroup Y (MenY) strains killed [33]. As there is no real-world evidence to estimate the vaccine effectiveness for cross-protection against IMD serogroups C, W and Y, these human serum bactericidal assay killing estimates were applied in the base case to approximate the vaccine effectiveness against serogroups W and Y. The model assumed no 4CMenB cross-protection against Nm serogroup A (MenA) or MenC IMD (due to the MenC UMV in place and very low incidence of serogroup A). Further, cross-protection against MenW and MenY was assumed only for individuals that are fully protected against MenB IMD, resulting in a conservative overall cross-protection estimate of 23.8% against Nm serogroups A, C, W, and Y (MenACWY).

Adverse events associated with 4CMenB vaccination include solicited local and systemic reactions that are transient and mild or moderate in nature, as observed in clinical trials [34] and confirmed by real-world data from the UK [35] and Germany [36, 37]. The model included costs related to medically attended fever. The adverse event rate was based on the frequency of medically attended fever for 4CMenB plus routine vaccines versus routine infant vaccinations, i.e. an incremental 0.48% for primary doses in infants [34]. 4CMenB infant UMV with vaccination at 2, 4 and 12 months of age could imply co-administration of 4CMenB with the measles, mumps, rubella and varicella vaccine (MMRV) as a catch-up vaccination at 12 months of age according to the current German national immunisation calendar [38]. Thus, in the absence of incremental rates available, the absolute rate of 1.1% for medically attended fever (4CMenB plus MMRV) was applied for the booster dose [34]. Therefore, the rate of at least one adverse event with a full vaccination series (2 + 1 schedule) was estimated to be 1.99%, assuming that adverse events occur independently of each other. Among these adverse events, 8.8% were calculated to need a hospital inpatient stay (see Supplemental Table S2) [34, 39].

The model used a vaccine price of €97.06 per dose (i.e. average payer price per dose across all 17 German healthcare regions via office supply [40]), with a corresponding wholesale price of €77.00 and assumed administration cost of €7.60 per dose, based on the average cost of administration for vaccines.

Further details of the model structure and input parameters are provided in Supplemental Fig. S1 and Table S1.

Calibration and Epidemiologic Inputs

As in the model by Christensen et al. [13], this model was calibrated in a two-step process: in the first step, the dynamic model was calibrated to the age-specific carriage prevalence reported by Christensen et al. [2]; and in the second step, the case–carrier ratio (used to calculate the number of IMD cases from the carriers in the decision tree) was calibrated to the age-specific IMD incidence in Germany. As IMD incidence varies unpredictably each year with outbreaks and periods of endemic disease [41], an average of incidence data over the period 2007 to 2015 was used, to account for the impact of MenC UMV starting in 2006, and to exclude a low MenB vaccination effect since MenB vaccination recommendation for risk groups was implemented in 2016. National surveillance data [42] were used to estimate IMD cases by yearly age groups (0 to 99+ years of age) for serogroups A, B, C, W, Y, X and “Other”.

Analysis

The public health impact was assessed in terms of reduction in overall IMD and MenB IMD incidence and numbers of cases and deaths following the introduction of 4CMenB infant UMV. The model also estimated the number needed to vaccinate (NNV) to prevent one case of MenB IMD (all IMD) (i.e. total number of vaccinations divided by total number of cases prevented), and number of adverse events expected post-vaccination to prevent one case of MenB IMD (all IMD) (i.e. NNV multiplied by rate of at least one adverse event with a full 4CMenB vaccination series [2 + 1 schedule]).

For the cost-effectiveness analysis of 4CMenB infant UMV, the key base case assumptions with alternatives implemented in each scenario analysis are presented in Table 1. Although the STIKO recommends a 3% discount rate for health outcomes in the base case and 1% in uncertainty analyses, the model used a 1% base case discount rate to account for the long-term impact of IMD [43]. In addition to the QALY losses for premature death and from sequelae in patients, the base case assumed a humanistic burden on the family and network of patients with IMD, with health spillover effects (i.e. family/network QALY losses) [24], a bereavement factor [26, 27] and a QALY loss for formal long-term caregivers [25] of IMD survivors with severe long-term sequelae. To account for the long-term negative health impact experienced by the family and close network of patients with IMD, as shown in a UK study, the QALY losses of patients due to acute disease and survivors with long-term sequelae were multiplied by a family and network factor of 48% [24]. The impact of death on the family was considered by applying a bereavement factor of 9% [27] to QALYs lost in fatal cases. For formal long-term caregivers of IMD survivors with severe sequelae, a utility decrement of 0.11 was assumed. A progressive scenario was developed, adding to the base case: (a) a quality of life adjustment factor (QAF) of 3, applied to QALY loss in cases with long-term sequelae, as previously recommended by the UK Joint Committee on Vaccination and Immunisation (JCVI) [44] and used in Christensen et al. (2014 and 2017 [26, 45]), to account for the societal preference to prevent uncommon but severe diseases such as IMD; and (b) incidence increased by 16.7% to account for potential underreporting (based on estimates for Germany [17]). A formal scenario applying the specifications for base case analysis according to the standard operating procedure (SOP) [43] of the STIKO was developed (STIKO SOP scenario), applying 3% discount rates for both costs and QALYs, and not considering the humanistic burden beyond the patient or any of the additional factors considered in the progressive scenario. The impact of varying discount rates (between 0 and 5%) on the 4CMenB cost-effectiveness was assessed in scenario analyses for the base case and STIKO SOP scenario (Supplemental Table S3). Recent evidence from Australia suggests 4CMenB is not likely to have an effect on carriage [46] and therefore no carriage effect was assumed in the base case. As a further extension of the base case, a carriage scenario assessed the potential effectiveness of 4CMenB in preventing acquisition of Nm carriage of MenB and MenACWY [47], and thus the impact of herd protection. Finally, to account for occasional epidemics and natural fluctuations of IMD incidence [48], high and low incidence scenarios were conducted with the incidence multiplied by 3 and 0.5, respectively. All input parameters are described in Supplemental Table S1.

Table 1 Base case assumptions and alternatives used in scenario analysis

As recommended by the STIKO [43], the base case analysis adopted the societal perspective, i.e. including direct costs reimbursed by the Statutory Health Insurance (SHI), costs of non-reimbursed patient co-payments and lost productivity costs (using the FCA to be applied for death and the acute phase of disease and the HCA to be applied for long-term sequelae including parents staying at home) in patients and their caregivers. Costs were expressed in euros (€) for the reference year 2015.

Both deterministic and probabilistic sensitivity analyses (DSA and PSA) were carried out to assess structural and parameter uncertainty. A univariate DSA was performed on all input parameters, while a PSA with n = 1000 replications was performed for the base case scenario excluding normative variables (i.e. discount rates, vaccine price and administration costs) as recommended by STIKO [43] and assuming no carriage protection and no QAF. As there is no official cost-effectiveness threshold in Germany [43], hypothetical thresholds of one, two, and three times the gross domestic product (GDP) per capita were applied, as proposed by the World Health Organization (WHO) [49], with ICERs below €37,046 and €111,138 representing a highly cost-effective and a cost-effective intervention [50]. For the PSA, the likelihood of replications having an ICER below WHO’s cost-effectiveness thresholds and the percentage of runs below the base case ICER were derived. The parameters with ranges used for the DSA and distributions for the PSA can be found in Supplemental Table S1.

Compliance with Ethics Guidelines

This analysis uses data from previously conducted studies and does not contain any new studies with human participants or animals performed by any of the authors.

Results

Public Health Impact

Following introduction of 4CMenB infant UMV, the model predicts a rapid decline in IMD incidence, primarily due to a reduction in MenB IMD. Figure 1 shows the impact of 4CMenB UMV on IMD incidence (MenB IMD and all IMD) in the age group 0–4 years over 100 years.

Fig. 1
figure 1

Base case percentage reduction in invasive meningococcal disease (IMD) incidence due to meningococcal serogroup B (MenB) and all serogroups, relative to no vaccination (age group 0–4 years). UMV universal mass vaccination

The largest public health impact was predicted in the group directly benefitting from vaccination, i.e. the age group of infants and children 0–4 years of age at highest risk. Herd protection was not considered in the base case. Among infants and young children aged 0–4 years, the model estimated there would be 497 MenB IMD (597 IMD) cases and 47 (56) deaths over 5 years (7687 MenB IMD [9239 IMD] cases and 722 [868] deaths over 100 years) without vaccination. A 4CMenB infant UMV would rapidly prevent around 40% (35%) and 42% (37%) of MenB IMD (all IMD) cases and deaths in 0–4-year-olds and in infants, respectively, 5 years after implementation of routine vaccination. The case reduction would remain at this stable level over 100 years (i.e. prevention of around 40% (35%) and 42% (37%) of both MenB IMD [all IMD] cases and deaths with a 100-year time horizon in these age groups). Based on the clinical and real-world evidence on duration of protection, vaccine effectiveness and model assumptions around adverse event rates, the model calculated the NNV; the model predicted 12,080 (11,536) infants would need to be vaccinated to prevent one case of MenB IMD (all IMD). Regarding adverse events (i.e. medically attended fever), there would be an estimated 241 (230) adverse events post-vaccination leading to an estimated 21 (20) hospital inpatient stays to prevent one case of MenB IMD (all IMD).

Health Outcomes and Cost-Effectiveness Results

The 4CMenB infant UMV is predicted to prevent 3154 MenB IMD (3303 IMD) cases, the development of 1370 (1435) long-term sequelae cases, 286 (300) cases needing long-term residential care and 291 (304) deaths, resulting in 10,023 (10,491) life years saved and 24,720 (25,878) QALYs gained over the model’s time horizon of 100 years. Over half (56%) of QALYs gained are due to prevention of sequelae and cases requiring long-term residential care (Table 2).

Table 2 Breakdown of all IMD cases, sequelae, deaths, QALYs and LYs lost (discounted 1%)

With no vaccination, MenB IMD (all IMD) disease management costs are estimated to be around €464.8 (€681.1) million over the model time horizon, with a significant additional lost productivity cost to society of €1.1 (€1.6) billion in Germany. The 4CMenB infant UMV is predicted to reduce disease management costs by around €75.4 (€79.0) million (savings of €9.5 [€10.0] million in acute care, €55.4 [€58.0] million in sequelae management, €9.6 [€10.0] million in special education costs and €0.90 [€0.94] million in public health outbreak management costs). When considering the significant impact of IMD on productivity, the UMV is predicted to save a total of €222.0 (€232.4) million in direct and indirect disease management costs (Table 3). The average annual undiscounted cost of vaccination was €133.4 million (€47.0 million discounted).

Table 3 Breakdown of base case costs (€, discounted 3%)

Considering the health benefits, cost savings and vaccination program costs, introducing a 4CMenB infant UMV in Germany is predicted to result in a gain in QALYs from prevention of IMD cases, sequelae and deaths, and increased costs driven by vaccination program costs, producing an incremental cost per QALY gained of €188,762 (including productivity losses) versus no vaccination (Table 4).

Table 4 Base case cost-effectiveness results for 4CMenB infant UMV versus no vaccination (discounted at 1% for QALYs and 3% for costs)

Scenario Analyses

The results of the scenario analyses compared to the base case are presented in Fig. 2 and Table 5. The STIKO SOP scenario, which produced a less cost-effective result (ICER €817,348/QALY) than the base case (ICER €188,762/QALY), excluded the QALY impact of IMD beyond the patient and applied a higher QALY discount rate (i.e. 3% vs. 1% in the base case). In the progressive scenario, assuming underreporting of IMD incidence and using the QAF to account for societal preferences, 4CMenB infant UMV appeared to be more cost-effective than the base case with an ICER of €77,941/QALY versus €188,762/QALY, respectively. Taking into consideration the potential carriage effect of 4CMenB (and subsequent herd protection) resulted in more IMD cases averted, and therefore more QALYs gained, with a more cost-effective result (ICER €109,090/QALY) than in the base case (Table 5). Further, assuming a low and high incidence scenario (varying the incidence by 50% and 300%) led to ICERs of €386,375/QALY and €56,935/QALY, respectively. The impacts of single parameter changes considered in the scenario analyses are presented in Fig. 2.

Fig. 2
figure 2

Impact of single parameters considered in scenario analyses on the 4CMenB cost-effectiveness using a stepwise approach. Note: base case and scenarios to the right of the base case use discount rates of 3% for costs and 1% for HO. 4CMenB four-component meningococcal serogroup B vaccine; GDP gross domestic product; HO health outcomes; ICER incremental cost-effectiveness ratio; QAF quality of life adjustment factor; QALY quality-adjusted life year; SOP standard operating procedure; STIKO Standing Committee on Vaccination (Ständige Impfkommission)

Table 5 Scenario analyses results (discounted), all age groups

Deterministic and Probabilistic Sensitivity Analyses

Figure 3 shows the ICER results when varying input parameters in the DSA. Varying the discount rate for health outcomes (from 1% to 5%) had the largest impact on cost-effectiveness, followed by the discount rate for costs (using 1% and 5%) and by MenB incidence (varying the base case incidence by around plus or minus 25%, see Supplement Table S1).

Fig. 3
figure 3

Tornado diagram showing the 10 DSA results with the largest impact on the incremental cost-effectiveness ratio (ICER). 4CMenB four-component meningococcal serogroup B vaccine; DSA deterministic sensitivity analysis; MenB meningococcal serogroup B; QALY quality-adjusted life year

At the hypothetical WHO cost-effectiveness threshold values of one, two, and three times the GDP per capita of 2015, routine 4CMenB had a low probability of being cost-effective (Fig. 4). The percentage of PSA runs below the base case ICER of €188,762 was 52.3%.

Fig. 4
figure 4

Cost-effectiveness acceptability curve (CEAC) for hypothetical cost-effectiveness thresholds of €37,046 (1 × GDP), €74, 092 (2 × GDP) and €111,138 (3 × GDP) per QALY gained. 4CMenB four-component meningococcal serogroup B vaccine; GDP gross domestic product; ICER incremental cost-effectiveness ratio; QALY quality-adjusted life year; UMV universal mass vaccination

Discussion

MenB (IMD) is an uncommon severe disease with potential life-threatening consequences, especially in infants. Introducing an infant 4CMenB UMV (2 + 1 dosing schedule at 2, 4 and 12 months of age) in Germany would result in a rapid decline in MenB (all IMD) incidence and deaths in the most vulnerable group of infants and young children 0–4 years of age, especially with a rapid increase in vaccine uptake. The sustainable reduction in incidence would occur within the first 5 years of introducing the UMV, with reductions of around 40% (35%) in MenB (all IMD) cases and deaths in young children. This represents a reduction of 3154 MenB (3303 all IMD) cases, 1370 (1435) long-term sequelae cases, 286 (300) cases requiring long-term residential care and 291 (304) deaths. The program would reduce the burden of direct and indirect treatment costs, saving €75.4 (€79.0) million in disease and outbreak management costs and special education costs in the base case, with an average annual undiscounted cost of vaccination of €133.4 million. The infant UMV would reduce the significant productivity loss associated with the disease, with indirect cost savings predicted to be €146.6 (€153.5) million. The model considers the burden of MenB IMD (IMD) to patients in the acute phase and from long-term sequelae, the QALY impact on their family/caregivers and the economic burden beyond the healthcare system (education, public health), with a resulting incremental cost per QALY gained in Germany of €188,762, from the societal perspective. This ICER falls within the magnitude of the rotavirus infant UMV in Germany [51], estimated to be around €117,000–143,000 [52]. Rotavirus also affects infants but is less severe than IMD and more common.

Routine infant 4CMenB was included in the UK UMV in 2015 in a 2 + 1 schedule (at 2, 4 and 12 months of age). After the first 3 years of the program with rapidly increasing vaccine uptake, real-world evidence showed a significant decline in IMD cases of 75% (95% confidence interval 64–81%) in the vaccine-eligible group aged 2–24 months olds [12]. Two regions of Italy that implemented routine infant 4CMenB using two different schedules also found significant declines in IMD cases in the vaccinated population (91% and 80% relative case reductions), and a higher vaccine impact (i.e. effect considered in both vaccinated and unvaccinated children) in the region with a vaccination strategy starting early at 2 months of age compared with 7 months of age (65% vs. 31%) [53]. Following other European countries, in June 2021, France also recommended 4CMenB starting at 2 months of age [11]. An early start of MenB vaccination (i.e. 2 months of age) is critical for a sustainable reduction of the MenB (IMD) induced burden of disease.

Our model is based on a dynamic transmission model by Huels et al. [54] which provided an extended version of the early model by Christensen et al. [55]. The economic results compare favourably to a previous IMD economic analysis conducted for Germany by Christensen et al. [13], which reported ICERs of over €500,000 and over €1.9 million per QALY gained for modelled strategies including and excluding indirect effects, respectively. In contrast to Christensen et al. [13], our model accounts for serogroups other than MenB that cause IMD and is thus able to include the effectiveness of 4CMenB against MenW and MenY IMD. In addition, our model utilises the latest data on the burden of disease in more detail with more accuracy, e.g. including the impact of IMD on 16 types of sequelae in patients (compared to three major and two minor sequelae in the Christensen et al. [13] model). Our model also includes the broader impact on QALY loss in family/caregivers beyond the patient. A recent claims database analysis found nearly a quarter of IMD cases in Germany suffered from sequelae [16], placing a considerable burden on the family/caregivers of survivors of IMD, as observed and measured in a large UK study of over 1200 families affected by IMD [24]. The costs included in our model were also based on a recent German costing study [17] providing a more comprehensive and accurate estimate of the lifetime costs of IMD, e.g. including costs of long-term institutional care and costs for all sequelae, which were not included in the previous German model. In Christensen et al. [13], the costs for the UMV were higher because of a 3 + 1 dose schedule, compared to the 2 + 1 dose schedule used here, based on the updated label [56], and as used in the UK and Portugal 4CMenB infant programs [12, 29].

As more evidence on input data becomes available, models need to use them to fully capture the value of vaccination. Including the full value using conservative health economic frameworks can be challenging, especially for UMVs for severe and uncommon diseases such as IMD with an unpredictable epidemiology [57]. The impact of new health economic modelling approaches that capture the full value of IMD vaccination [57] versus the STIKO modelling framework was illustrated in scenario analyses. For example, normative adaptations to the base case analysis according to STIKO’s framework decreased the ICER from €817,348 to a base case of €188,762 (reduction of 77%) with an initial reduction of − 25 percentage points due to consideration of QALY losses beyond the patient (i.e. family QALY losses, a bereavement factor and QALY losses for formal long-term caregivers), and a further reduction of − 52 percentage points due to applying a lower discount rate of 1% for health outcomes to account for the long-term health benefits of vaccination [58, 59]. Discounting in modelling of vaccinations compared to other healthcare interventions has also been debated, since the costs of a vaccination program occur immediately while their health benefits may only be visible several years later [60, 61]. By discounting the benefits of vaccination more heavily or equally compared to costs, vaccinations appear less beneficial than health interventions with rapidly evident benefits. Recent evidence from a French database analysis [62] has suggested that IMD significantly reduces life expectancy in survivors of the acute phase. Therefore, the life years (and QALYs) gained following vaccination in this analysis, and the subsequent cost-effectiveness of 4CMenB, are likely to be underestimated. Future analyses should consider these additional benefits of 4CMenB vaccination with respect to the impact on the family and close network and to account for the long-term benefits of vaccination.

The current recommendation in Germany is for 4CMenB to be used in individuals at increased risk of IMD, such as household contacts of IMD cases and people with underlying immunologic deficiencies. In addition to immune deficiencies, a recent database analysis of IMD cases in France suggested that chronic medical conditions as well as low socioeconomic status may be risk factors for IMD hospitalisation [63]. A UMV can reduce the uncertainty due to unknown risk factors and protect those who may not be able to afford vaccination, as well as provide greater health benefits than targeted risk group vaccination recommendations, by preventing more disease in a larger group. The results of this analysis suggest that a 4CMenB infant UMV will have important benefits in preventing this severe life-threatening disease with the highest burden in infants and adolescents, at a lower cost-effectiveness ratio than previously estimated [13], and can be used to support decision-making towards a MenB infant UMV in Germany.

A key strength of this study is the use of a model that allows the comprehensive burden of IMD to be considered when evaluating the UMV, i.e. the model includes the main serogroups causing IMD for the assessment of 4CMenB cross-protection effectiveness against multiple serogroups, a decision tree which includes a large range of potential short- and long-term sequelae resulting from IMD, and dynamic transmission for the evaluation of carriage and herd protection. As IMD is an uncommon disease, there are still many gaps in the data available especially for Germany. The model was, therefore, partly informed by input data from other countries (e.g. sequelae probabilities and utilities), as is common practice in economic evaluation. The model also did not consider the effects of potential strain replacement. To account for potential data uncertainty, numerous DSAs, a PSA and scenario analyses were conducted. In addition, IMD remains a disease with an unpredictable incidence and risk of outbreaks, making it difficult to model accurately. Existing models therefore need to make assumptions about incidence over time, and this model uses an average of incidence data over multiple years.

Conclusions

More evidence is now available on the burden and costs of IMD in Germany, and recent real-world evidence from the UK and Italy has demonstrated the significant benefits of routine 4CMenB vaccination. This updated analysis can inform decision-makers on the potential public health and health economic impact of a 4CMenB infant UMV in Germany. Our model showed that a UMV is predicted to rapidly reduce IMD cases and deaths in infants and young children, as well as the long-term burden of disease in survivors of the acute phase. Considering the broad-ranging impact to patients and their families/caregivers, routine 4CMenB is expected to provide additional health benefits to society at a cost of around €189,000/QALY gained and, with a more progressive scenario, results in an incremental cost of around €78,000/QALY gained.