Studies on the real-life effect of the BNT162b2 vaccine for Coronavirus Disease 2019 (COVID-19) prevention are urgently needed. In this study, we conducted a retrospective analysis of data from the Israeli Ministry of Health collected between 28 August 2020 and 24 February 2021. We studied the temporal dynamics of the number of new COVID-19 cases and hospitalizations after the vaccination campaign, which was initiated on 20 December 2020. To distinguish the possible effects of the vaccination on cases and hospitalizations from other factors, including a third lockdown implemented on 8 January 2021, we performed several comparisons: (1) individuals aged 60 years and older prioritized to receive the vaccine first versus younger age groups; (2) the January lockdown versus the September lockdown; and (3) early-vaccinated versus late-vaccinated cities. A larger and earlier decrease in COVID-19 cases and hospitalization was observed in individuals older than 60 years, followed by younger age groups, by the order of vaccination prioritization. This pattern was not observed in the previous lockdown and was more pronounced in early-vaccinated cities. Our analysis demonstrates the real-life effect of a national vaccination campaign on the pandemic dynamics.
An effective and safe vaccination campaign is urgently needed to halt the rapid spread of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infections and the resulting disease, COVID-19. The BNT162b2 vaccine, developed by BioNTech in cooperation with Pfizer, is a lipid nucleoside-modified RNA encoding the SARS-CoV-2 full-length spike protein1. Results from a phase 3 randomized placebo-controlled trial demonstrated that a two-dose regimen in a 21-d interval conferred 95% protection against laboratory-confirmed COVID-19 infection in individuals 16 years of age or older2. On 11 December 2020, the Food and Drug Administration issued an Emergency Use Authorization for emergency use of the vaccine for the prevention of COVID-19 (ref. 3), and, after that, an emergency use of the vaccine was also issued by the Israeli Ministry of Health (MOH).
On 20 December 2020, Israel launched a national COVID-19 vaccination campaign4, in which BNT162b2 vaccines were administered. The Israeli health system comprises four health maintenance organizations (HMOs), and vaccinations were widely available, according to a prioritization schedule determined by the Israeli MOH. During the early phases of the distribution process, individuals considered as being at high risk for COVID-19 were prioritized for vaccination, including individuals older than 60 years, nursing home residents, healthcare workers and individuals with severe comorbidities. The vaccination campaign was further expanded for individuals aged 55 years and older5 and 40 years6 and older on 12 January 2021 and 19 January 2021, respectively. On 21 January, individuals aged 16–18 years were also prioritized for vaccination. On 28 January, the vaccination campaign expanded to those aged 35 and older7. On 4 February, all individuals aged 16 years and older were eligible to receive the vaccine. However, the HMOs were still instructed to focus their efforts on those aged 50 years and older8. As of 24 February, individuals with a history of severe allergic reactions to the vaccine components, individuals who recovered from COVID-19 or individuals younger than 16 years of age (with the exception of children with severe chronic diseases) were not eligible to receive the vaccine. Starting 3 March 2021, recovered individuals were eligible for a single vaccine dose 3 months after their previous infection date.
The national vaccination campaign has led Israel to having one of the highest rates of vaccinated individuals per capita, with 48.8%, 34% and 7.5% of the population having received the first or the second vaccine dose or having recovered from COVID-19, respectively, as of 24 February 2021, or 68.7%, 48% and 8%, respectively, taking into account population older than 16 years—the population currently eligible for vaccination. In parallel, during the early weeks of the vaccination campaign, the number of cases and hospitalized patients rapidly increased, along with the local emergence of the B1.1.7 variant9, leading the government to impose a third lockdown on 8 January 2021. This lockdown was gradually eased starting on 7 February 2021.
When evaluating the effects of vaccines, there are two complementary forms of evaluation. One is measuring the direct effects of the vaccine on the vaccinated individual (termed ‘vaccine effectiveness’); the other is measuring the overall effect of the vaccination program on an entire population (termed ‘vaccine impact’)10. On the individual level, preliminary studies from two of the largest Israeli HMOs have attempted to estimate the real-life effectiveness of the vaccine. The first reported an efficacy of 51% for the first dose after 13–24 d11, whereas the second reported an efficacy of 46% and 92% after 14–20 d from the first dose and 7 or more days from the second dose of the vaccine, respectively12. Another report estimated that the vaccine effectiveness is above 95% 3–4 weeks after the second dose13. However, to our knowledge, very few studies14 thus far have analyzed the effect of the vaccination campaign on the patterns of pandemic dynamics at the population level. As Israel is one of the first countries to implement a vaccination campaign of this magnitude, we think that this quantification might be of interest to many countries worldwide. A summary of the main findings and limitations of the study is provided in Table 1.
Starting on 20 December 2020—the initiation of the vaccination campaign—the number of vaccines administered per day began at approximately 50,000, quickly rose to over 150,000 by 24 December and reached a maximum of 231,010 vaccinations on 21 January 2021 (Fig. 1). Vaccinations per day for each age group are shown in Extended Data Fig. 1. By 7 January 2021, almost 70% of the population over 60 years old had already been vaccinated (first dose) or recovered, increasing gradually to 88.5% (first dose) and 81% (both doses) by 24 February. Cumulative percentages of recovered or vaccinated individuals by age group are shown in Extended Data Fig. 2.
The temporal changes in the number of new COVID-19 cases and hospitalizations in Israel from 18 December 2020 to 24 February 2021 are summarized in Figs. 2 and 4. Several days after the initiation of the lockdown on 8 January 2021 and the beginning of the administration of the second vaccine doses on 10 January, the number of new COVID-19 cases in individuals aged 60 years and older reached a peak. This peak was followed by a peak in mild, moderate or severe hospitalization of individuals and a later peak in severe hospitalization of the same age group. Between 15 January and 24 February, the number of new cases and hospitalizations in this age group declined. As several potential factors other than the vaccines could have influenced this decline, we aimed to estimate the specific contribution of the vaccination campaign to the observed patterns.
We first compared individuals 60 years and older, who were prioritized to receive the vaccine earlier, to younger individuals (Fig. 2 and Supplementary Table 1). The decrease in the number of cases and hospitalizations was larger and earlier in individuals 60 years and older compared to younger individuals. Moreover, the decrease in these clinical measures was according to the order of real-life vaccination rate (Extended Data Fig. 3), which was guided by the prioritization schedule from the Israeli MOH. For example, a decrease of 45% versus 28% in the percentage of positive tests and 68% versus 22% in hospitalizations compared to the peak was observed in individuals 60 years and older compared to individuals aged 20–39 years. This is also evident in a considerable shift toward younger ages in the distribution of ages of patients with severe COVID-19 (Fig. 4). To allow youth to attend their school exams, adolescents (age 16–18 years) were also prioritized early in the vaccination campaign. Many young adults (age 18–21 years) serving in the Israel Defense Forces were also prioritized. Notably, COVID-19 cases and the positivity rates of diagnostic tests dropped more rapidly in this group (age 16–21 years) compared to similar age groups that were not vaccinated yet (14–15 years and 22–23 years) (Extended Data Fig. 4).
Figure 3 presents a set of comparisons of clinical measures between two time periods: a period after the second national lockdown implemented by the Israeli government on 18 September 2020 (Fig. 3a–d), and after the third national lockdown, implemented on 8 January 2021 (Fig. 3a–d). Although all clinical measures had almost the same dynamics for all age groups during the first period (second lockdown), these dynamics differed substantially across age groups in the second period (third lockdown + vaccine drive), where a larger and earlier decline in older individuals (older than 60 years) compared to younger individuals was apparent.
The analysis between early-vaccinated cities and late-vaccinated cities (Methods) revealed a larger and earlier decrease in the number of COVID-19 cases and hospitalizations of individuals 60 years and older in cities vaccinated early compared to late-vaccinated cities (Fig. 5 and Supplementary Table 2). For example, in early-vaccinated cities, there was a decrease of 88% in cases and of 79% in severe hospitalizations compared to peak values, whereas, in late-vaccinated cities, a smaller decrease of 78% in cases and 66% in severe hospitalizations was observed. Finally, to obtain a higher geographic resolution, we compared between early-vaccinated geographical statistical areas (GSAs) and late-vaccinated GSAs (Methods, Extended Data Fig. 5 and Supplementary Table 3). This analysis revealed similar findings as the city-level analysis.
Here we show early signs for the effect of a national vaccination campaign in Israel on the pandemic dynamics. Our analysis revealed that a little over 2 months after the initiation of the vaccination campaign, with 85% of individuals older than 60 years already vaccinated with two doses (24 February 2021), there was an approximately 77% drop in cases, a 45% drop in positive test percentage, a 68% drop in hospitalizations and a 67% drop in severe hospitalizations compared to peak values. Although multiple other factors besides the vaccines might have influenced these results, several observations suggest that these patterns are likely to be driven, to a considerable degree, by the vaccines. First, the decline in the measures above is greater in individuals 60 years and older who were prioritized to receive the vaccine earlier, with consecutive drops observed in younger age groups later, according to the order of vaccine prioritization, including earlier drops in some young age groups (16–21 years) prioritized over older age groups (21–35 years). Moreover, the decrease in the clinical measures that we analyzed occurred only after more than 50% of the population in a given age group had been vaccinated by the first dose or recovered (Fig. 2). Second, the effect was greater in cities and GSAs where a higher fraction of individuals were vaccinated earlier. Finally, we did not observe a similar pattern of a larger and faster decline of cases and hospitalizations in older individuals during the previous lockdown implemented in Israel (between 18 September 2020 and 18 October 2020), in which all clinical measures had similar dynamics in all age groups (Fig. 3 and Extended Data Figs. 3–7).
Although previous reports, both in a clinical trial setting2,11 and on real-life data12, have indicated efficacy of the vaccine after the first dose, the improvement in the number of hospitalized patients in Israel was evident approximately 3–4 weeks after initiation of the vaccination campaign. We think that this has several explanations. First, the real-life effectiveness might be different from the efficacy reported in the clinical trial. In particular, the logistics of refrigeration, storage, transportation and on-site administration of the vaccines in real-world settings and during a rapid deployment campaign could have been imperfect, thus lowering effectiveness. Second, the effect might be heterogeneous and population dependent. For example, it is possible that older individuals, who were prioritized earlier in the vaccination campaign, could have a reduced or belated response to the vaccination due to a deterioration in both innate and adaptive immune function, also termed immunosenescence, as was previously shown for other vaccines15,16. Third, it is possible that the effectiveness of the vaccine is reduced in light of the emergence of new strains, such as the B.1.1.7 variant17 (which was the dominant strain in Israel in February 202118) and the 501.V2 variant19, which might be associated with an increased risk of death20.
Even if the real-life effectiveness of the vaccine is similar to the efficacy reported in the clinical trial, as shown by Dagan et al.12, the effect of the vaccination program on the population as a whole depends on additional factors, including the national vaccine coverage, vaccine allocation among different subgroups of individuals and social mixing of the different groups that could affect disease transmission through indirect effects. It is also possible that vaccinated individuals might alter their behavior (for example, mobility) and decrease adherence to public health prevention guidance (for example, physical distancing and face masks), thereby increasing viral transmission. Notably, mobility data in different districts in Israel throughout the study period (Extended Data Fig. 8) show that mobility was influenced mainly by the restrictions imposed during the lockdown and the loosening of these restrictions thereafter. As expected by Israel’s small geographic size, the variation between different districts was relatively small, and it was difficult to ascertain if it was affected by the small variation in the vaccination rate. Future studies are, therefore, needed to assess the effects of the vaccination campaign on different aspects of human behavior.
Another consideration is that viral transmission could also occur in the vaccination sites themselves. The vaccination sites should be large and ventilated to decrease the probability of transmission on site. Finally, there is a clear pattern where areas in Israel with higher infection rates and a lower socioeconomic status have lower vaccination rates, despite widespread vaccine availability21.This trend might also diminish or delay the overall effect of the campaign as those who are at a higher risk of being infected are less vaccinated. Further efforts should, therefore, be made to encourage these populations to vaccinate and make the vaccines even more easily accessible to them. We note that exact individual-level efficacy numbers cannot be deduced from our analysis, and that, owing to all of the above issues, our results might be consistent with efficacies that are either lower or higher than those reported in the original clinical trial.
Our study had several limitations. First, it was an observational study as opposed to a randomized clinical trial, and, therefore, causal effects are difficult to infer. Second, the comparison between the second and third lockdown might be influenced by factors such as the total number of COVID-19 cases in the beginning of each lockdown, testing policy, hospitalization policy and public compliance with the restrictions that could have changed with time. Similarly, differences among cities might be influenced by behavioral and social differences beyond availability of vaccines. However, none of these factors was likely to cause the different patterns observed in the different age groups reported here. Finally, the effects of the vaccination campaign observed here could be influenced by factors specific to Israel and its healthcare system, in which all citizens are mandated to join one of the official non-profit health insurance organizations. Financial and regional disparities in other healthcare systems might affect the distribution and availability of vaccinations, thereby influencing the real-life efficacy of the vaccines.
Overall, we show an analysis of large-scale, real-world data from Israel demonstrating real-life effectiveness of a national vaccination campaign. Although our findings are preliminary, they have major public health implications for the struggle against the COVID-19 pandemic. More studies aimed at assessing the effectiveness of the vaccination on reducing the transmission of SARS-CoV-2 are needed, both on the individual level and on the population level, with larger longitudinal follow-up and in additional populations.
A retrospective analysis was conducted on data originating from the Israeli MOH from 28 August 2020 to 24 February 2021. The data included information on age, sex, date of positive SARS-CoV-2 polymerase chain reaction (PCR) test, date of hospitalization, clinical state during hospitalization and date of death or recovery for each individual. Data on national vaccination are available online (http://data.gov.il/dataset/covid-19/) and include the number of daily vaccine doses, separated to first and second doses, administered in each city by age groups (a scale of 10 years). Recovered individuals were included in the vaccinated group in all of the analyses, as previous studies analyzing the antibody responses after recovery showed persistent antibody titers against the SARS-CoV-2 spike protein for several months after infection23. Throughout the study period, these individuals were not eligible to receive the vaccine. A total of 3,210,200 individuals vaccinated with both doses of the vaccine and 711,949 recovered individuals were included in the analysis. An exemption from institutional review board approval was determined by the Israeli MOH as part of an active epidemiological investigation, based on use of anonymous data only and no medical intervention.
The temporal changes in weekly numbers of several clinical measures were analyzed, including positive COVID-19 cases, percentage of positive tests, hospitalized patients and hospitalized patients in a severe state. COVID-19 cases were identified by a positive SARS-CoV-2 PCR test. Classification of the hospitalization severity was based on the following clinical criteria, applied on 13 July 2020 by the Israeli MOH24 based on National Institutes of Health25 and World Health Organization26 definitions: Mild illness—individuals who have any of the various signs and symptoms of COVID-19 (for example: fever, cough, malaise and loss of taste or smell); Moderate illness—individuals who have evidence of pneumonia by a clinical assessment or imaging; Severe illness—individuals who have a respiratory rate >30 breaths per minute, SpO2 <93% on room air at sea level or ratio of arterial partial pressure of oxygen to fraction of inspired oxygen (PaO2/FiO2) <300 mmHg; and Ventilated/Critical—individuals with respiratory failure who require ventilation (invasive or non-invasive) or who have multi-organ dysfunction or shock. In this study, we denoted all patients in a severe case or worse as severe (including ventilated and critical patients).
To distinguish the effect of the vaccination campaign from other factors that might influence COVID-19 morbidity and mortality, including a third lockdown imposed in Israel during this time period, the following comparisons of the dynamic of the clinical measures mentioned above were performed. First, we compared between individuals aged 60 years and older, who were the population prioritized to receive the vaccine earlier, and younger individuals, who were prioritized according to MOH guidelines (Fig. 2). Second, we compared between the decline in the number of cases and hospitalizations observed after the initiation of the second national lockdown imposed by the Israeli government on 18 September 2020, with the decline observed after the initiation of the third national lockdown, imposed while the vaccination program was in place, on 8 January 2021 (Fig. 3).
Third, cities with a high percentage of individuals who were vaccinated early were compared to cities with a low percentage. For every city with more than 5,000 residents aged 60 years and older, the percentage of these individuals who received the first dose of the vaccine was calculated. Early-vaccinated cities were defined as the top ten cities with the highest percentage of individuals older than 60 years who were either vaccinated or recovered from COVID-19 by 10 January 2021 (ten cities with a total population of 641,276). Late-vaccinated cities were defined as the ten bottom cities with the lowest percentage of individuals older than 60 years who were vaccinated by 10 January 2021 (ten cities with a total population of 1,845,759) (Extended Data Fig. 9).
Finally, data with a higher geographical resolution, termed GSAs, were analyzed. The GSAs are small, relatively homogeneous intra-city units defined by the Israeli Bureau of Statistics, with an average of 3,000 residents, within cities with more than 10,000 inhabitants. Data on vaccination for the GSAs were available without age group separation, although the national vaccination policy described earlier still holds information regarding the timing of each age group’s vaccination. Out of 1,385 GSAs, 1,148 had more than 500 residents aged 60 years and older. Out of these 1,148 GSAs, the 400 with the highest vaccination rate by 10 January 2021 (3 weeks after the beginning of the vaccine drive) were denoted as early-vaccinated GSAs and the 400 with the lowest vaccination rate by 10 January 2021 were denoted as late-vaccinated GSAs.
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
The data that support the findings of this study originate from the Israeli Ministry of Health.
National age group-level vaccination data: https://data.gov.il/dataset/covid-19/resource/57410611-936c-49a6-ac3c-838171055b1f. Aggregated town-level and age group vaccination data are available at https://data.gov.il/dataset/covid-19/resource/12c9045c-1bf4-478a-a9e1-1e876cc2e182. Aggregated GSA-level infection, hospitalization and vaccination data are available at https://data.gov.il/dataset/covid-19/resource/d07c0771-01a8-43b2-96cc-c6154e7fa9bd. Case and hospitalization data are derived from confidential individual data and are not publicly available.
Source code is available at https://github.com/hrossman/Patterns-of-covid-19-pandemic-dynamics-following-deployment-of-a-broad-national-immunization-program. All analyses were performed using the statistical Python version 3.6 and matplotlib 3.10.
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We thank M. Bruhim, M. Goldberg and E. Sitbon for their contributions to our efforts. H.R. is supported by the Israeli Council for Higher Education via the Weizmann Data Science Research Center and by a research grant from Madame Olga Klein-Astrachan.
The authors declare no competing interests.
Peer review information Nature Medicine thanks the anonymous reviewers for their contribution to the peer review of this work. Jennifer Sargent was the primary editor on this article and managed its editorial process and peer review in collaboration with the rest of the editorial team.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Daily number of administered vaccination doses by age groups, first dose (blue bars) and second dose (green bars).
Cumulative percentage of each age-group recovered or vaccinated. Vaccinated population that received the first dose is shown in blue; and the vaccinated population that received the second dose is shown in green. Recovered population is shown in gray.
Extended Data Fig. 3 Comparison between age groups centered at 50% received first dose of vaccine or recovered.
Comparison between age groups 20–39 (red), 40–49 (green), 50–59 (orange) and over 60 (blue) years old in a, Percent drop of new positive cases from peak value b, Percent from the peak of PCR tests positive results percentage c, Percent from the peak of new hospitalizations d, Percent from the peak of new severe cases. All curves are centered at the date in which 50% of the age group population has received the first dose or recovered.
Comparison between age groups 14–15 (blue), 16–17 (orange), 18–21 (green) and 22–23 (red) years old in a, Percent drop of new positive cases from peak value at the time period around the second lockdown b, Percent from the peak of PCR tests positive results percentage at the time period around the second lockdown c, Percent drop of new positive cases from peak value at the time period around the third lockdown d, Percent from the peak of PCR tests positive results percentage at the time period around the third lockdown. In a, b “Day 0” represents the second lockdown start date, September 18th 2020. In c, d “Day 0” represents the third lockdown start date, January 8th 2021. In all figures the lockdown time period is displayed as gray filling.
Comparison between age groups 0–59 years old and 60+ years old from early- and late-vaccinated GSAs. In all figures the third lockdown time period is shown as gray filling. Note: Figures a-f are presented with different y-axis scales in order to highlight relative within-population trends. Age group 0–59 is shown as a purple line in a,c,e and as a brown line in b,d,f. Age group 60+ is shown as a green line in a,c,e and as a red line in b,d,f. a, Rolling weekly sum of new positive cases in early-vaccinated GSAs. b, Rolling weekly sum of new positive cases in late-vaccinated GSAs. c, Rolling weekly sum of new mild, moderate or severe hospitalizations in early-vaccinated GSAs. d, Rolling weekly sum of new mild, moderate or severe hospitalizations in late-vaccinated GSAs. e, Rolling weekly sum of new severe hospitalizations in early-vaccinated GSAs. f, Rolling weekly sum of new severe hospitalizations in late-vaccinated GSAs. g, Percentage of individuals vaccinated or recovered in time in early-vaccinated GSAs. h, Percentage of individuals vaccinated or recovered in time in late-vaccinated GSAs. A summary of this figure is shown in Supplementary Table 3.
Extended Data Fig. 6 Early-vaccinated and late-vaccinated cities comparison around September lockdown.
Comparison between age groups 0–59 years old and 60+ years old from cities with most of the population vaccinated early and cities with most of the population vaccinated late. In all figures the lockdown time period is shown as gray filling. Note: Figures a-f are presented with different y-axis scales in order to highlight relative within-population trends. Age group 0–59 is shown as a purple line in a,c,e and as a brown line in b,d,f. Age group 60+ is shown as a green line in a,c,e and as a red line in b,d,f. a, Rolling weekly sum of new positive cases in early-vaccinated cities. b, Rolling weekly sum of new positive cases in late-vaccinated cities. c, Rolling weekly sum of new mild, moderate or severe hospitalizations in early-vaccinated cities. d, Rolling weekly sum of new mild, moderate or severe hospitalizations in late-vaccinated cities. e, Rolling weekly sum of new severe hospitalizations in early-vaccinated cities. f, Rolling weekly sum of new severe hospitalizations in late-vaccinated cities.
Extended Data Fig. 7 Early-vaccinated and late-vaccinated GSAs comparison around September lockdown.
Comparison between age groups 0–59 years old and 60+ years old from geographical statistical areas (GSAs) with most of the population vaccinated early and GSAs with most of the population vaccinated late. In all figures the second lockdown is shown as gray filling. Note: Figures a-f are presented with different y-axis scales in order to highlight relative within-population trends. Age group 0–59 is shown as a purple line in a,c,e and as a brown line in b,d,f. Age group 60+ is shown as a green line in a,c,e and as a red line in b,d,f. a, Rolling weekly sum of new positive cases in early-vaccinated GSAs. b, Rolling weekly sum of new positive cases in late-vaccinated GSAs. c, Rolling weekly sum of new mild, moderate or severe hospitalizations in early-vaccinated GSAs. d, Rolling weekly sum of new mild, moderate or severe hospitalizations in late-vaccinated GSAs. e, Rolling weekly sum of new severe hospitalizations in early-vaccinated GSAs. f, Rolling weekly sum of new severe hospitalizations in late-vaccinated GSAs.
Israel mobility data (See https://www.google.com/covid19/mobility). Mobility trend per district compared to baseline mobility, which is defined as the mobility in the date in which the vaccination campaign was initiated. In all panels, the time period of the lockdown is shown as gray filling. a, retail and recreation mobility. b, grocery and pharmacy mobility. c, parks mobility. d, transit stations mobility. e, workplaces mobility. f, residential mobility.
Extended Data Fig. 9 Cumulative percentage of vaccinated population from age group 60+, in cities with more than 5,000 residents in this age group.
Cumulative percentage of vaccinated population from age group 60+, in cities with more than 5,000 residents in this age group. Early-vaccinated cities are shown as green lines, late-vaccinated cities are shown as red lines. Other cities are shown as gray lines.
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Rossman, H., Shilo, S., Meir, T. et al. COVID-19 dynamics after a national immunization program in Israel. Nat Med 27, 1055–1061 (2021). https://doi.org/10.1038/s41591-021-01337-2
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