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Understanding the impact of the COVID-19 pandemic response on GI infection surveillance trends in England, January 2020–April 2022

Published online by Cambridge University Press:  25 August 2023

Nicola K. Love Open the ORCID record for Nicola K. Love [Opens in a new window] ,
Amy Douglas ,
Saheer Gharbia ,
Helen Hughes ,
Roger Morbey Open the ORCID record for Roger Morbey [Opens in a new window] ,
Isabel Oliver ,
Gillian E. Smith Open the ORCID record for Gillian E. Smith [Opens in a new window]  and
Alex J. Elliot Open the ORCID record for Alex J. Elliot [Opens in a new window]
Nicola K. Love*
Affiliation:
North East Field Services, Health Protection Operations, UK Health Security Agency, Newcastle upon Tyne, UK National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Gastrointestinal Infections, University of Liverpool, Liverpool, UK
Amy Douglas
Affiliation:
Gastrointestinal Infections and Food Safety (One Health) Division, UK Health Security Agency, London, UK
Saheer Gharbia
Affiliation:
Gastrointestinal Infections and Food Safety (One Health) Division, UK Health Security Agency, London, UK
Helen Hughes
Affiliation:
National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Gastrointestinal Infections, University of Liverpool, Liverpool, UK Real-time Syndromic Surveillance Team, Field Service, Health Protection Operations, UK Health Security Agency, Birmingham, UK Farr Institute@HeRC, University of Liverpool, Liverpool, UK
Roger Morbey
Affiliation:
Real-time Syndromic Surveillance Team, Field Service, Health Protection Operations, UK Health Security Agency, Birmingham, UK National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Emergency Preparedness and Response, King’s College London, London, UK
Isabel Oliver
Affiliation:
Science Group, UK Health Security Agency, London, UK National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Behavioural Science and Evaluation, Population Health Sciences, University of Bristol, Bristol, UK
Gillian E. Smith
Affiliation:
National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Gastrointestinal Infections, University of Liverpool, Liverpool, UK Real-time Syndromic Surveillance Team, Field Service, Health Protection Operations, UK Health Security Agency, Birmingham, UK National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Emergency Preparedness and Response, King’s College London, London, UK
Alex J. Elliot
Affiliation:
National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Gastrointestinal Infections, University of Liverpool, Liverpool, UK Real-time Syndromic Surveillance Team, Field Service, Health Protection Operations, UK Health Security Agency, Birmingham, UK National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Emergency Preparedness and Response, King’s College London, London, UK
*
Corresponding author: Nicola K Love; Email: Nicola.Love@ukhsa.gov.uk
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Abstract

Stepwise non-pharmaceutical interventions and health system changes implemented as part of the COVID-19 response have had implications on the incidence, diagnosis, and reporting of other communicable diseases. Here, we established the impact of the COVID-19 outbreak response on gastrointestinal (GI) infection trends using routinely collected surveillance data from six national English laboratory, outbreak, and syndromic surveillance systems using key dates of governmental policy to assign phases for comparison between pandemic and historic data. Following decreases across all indicators during the first lockdown (March–May 2020), bacterial and parasitic pathogens associated with foodborne or environmental transmission routes recovered rapidly between June and September 2020, while those associated with travel and/or person-to-person transmission remained lower than expected for 2021. High out-of-season norovirus activity was observed with the easing of lockdown measures between June and October 2021, with this trend reflected in laboratory and outbreak systems and syndromic surveillance indicators. Above expected increases in emergency department (ED) attendances may have reflected changes in health-seeking behaviour and provision. Differential reductions across specific GI pathogens are indicative of the underlying routes of transmission. These results provide further insight into the drivers for transmission, which can help inform control measures for GI infections.

Keywords

COVID-19foodborne infectionsgastrointestinal infectionsnon-pharmaceutical interventionssurveillance
Type
Original Paper
Information
Epidemiology & Infection , Volume 151 , 2023 , e147
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Introduction

As a result of the COVID-19 pandemic, governments implemented stepwise non-pharmaceutical intervention (NPI) measures designed to mitigate the impacts of the virus and reduce transmission, while undertaking changes to healthcare provision and patient management to reduce the strain on health systems. Many of the measures introduced such as improved hand hygiene, reduced social contact, increased environmental cleaning, and the closure of premises are control measures effective in reducing the incidence of other communicable diseases [Reference Hawker, Begg, Blair, Reintjes and Weinberg1].

Gastrointestinal (GI) infections are an important cause of morbidity and mortality globally, placing a considerable burden on primary and secondary healthcare services [Reference Tam, Rodrigues, Viviani, Dodds, Evans, Hunter, Gray, Letley, Rait, Tompkins and O’Brien2]. We previously reported on marked changes in the trends of GI infections during the initial 6 months of the COVID-19 outbreak response in England (the first partial lockdown and relaxation of initial lockdown measures; [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3]). This initial work demonstrated a 52% decrease in GI outbreaks and a 34% decrease in laboratory-confirmed cases reported during the first national lockdown with figures remaining lower than historic averages once measures were eased. Similar rapid reductions in gastroenteric pathogens were consistently observed across surveillance systems in other countries with the onset of the pandemic in 2020, with decreases estimated to be around 70–80% for reported viral GI outbreaks [Reference Bruggink, Garcia-Clapes, Tran, Druce and Thorley4, Reference Eigner, Verstraeten and Weil5] and between 19 and 55% for laboratory-confirmed bacterial GI pathogens [Reference Ahn, Park, Lim, Chae, Yun, Lee, Kim, Choi and Yi6Reference Kraay, Han, Kambhampati, Wikswo, Mirza and Lopman10]. Several hypotheses were proposed to explain the reductions in GI pathogens observed. These included changes in health-seeking behaviour, limited testing, changes in healthcare provision, and true decreases in incidence. Following the lifting of all control measures in England on 24 February 2022, we now present an update to our initial study, which aims to establish the impact of subsequent pandemic lockdowns, control measures, and easing of measures on GI infection surveillance trends over the pandemic response in England.

Methods

A retrospective ecological study was conducted by performing secondary analyses on routinely collected national surveillance data from six national UK Health Security Agency (UKHSA) coordinated systems, as described previously [Reference Jördens, Loosen, Seraphin, Luedde, Kostev and Roderburg8]. Systems included outbreak monitoring (HPZone), laboratory notifications from all National Health Service (NHS) laboratories (Second Generation Surveillance System; SGSS), and syndromic surveillance systems (NHS 111 telehealth consultations, general practitioner (GP) ‘in-hours’ and ‘out-of-hours’ consultations, and emergency department (ED) attendances [Reference Kara-Zaïtri, Gelletlie and Schweiger11, Reference Smith, Elliot, Lake, Edeghere, Morbey, Catchpole, Heymann, Hawker, Ibbotson, McCloskey and Pebody12]).

For laboratory and outbreak datasets, the COVID-19 pandemic period was defined as 30 December 2019 to 30 April 2022 inclusive, with historic comparator data covering 29 December 2014 to 29 December 2019 inclusive aggregated by ISO week. For syndromic surveillance indicators, the historic comparator period covered 31 December 2018 to 29 December 2019 inclusive. Data were further split into COVID-19 pandemic ‘phases’ for comparison, determined by the stringency of control measures using the Oxford Severity Scale [Reference Mathieu, Ritchie, Rodés-Guirao, Appel, Giattino, Hasell, Macdonald, Dattani, Beltekian, Ortiz-Ospina and Roser13] and key dates of UK governmental policy ([14]; Figure 1). These phases were defined as follows: ‘phase 1’, the pre-outbreak period; ‘phase 2’, advising of hygiene and social distancing measures prior to the first national lockdown; ‘phase 3’, the first national lockdown; ‘phase 4’, the gradual easing of restriction measures; ‘phase 5’, the reimplementation of restriction measures; ‘phase 6’, the second and third national lockdowns; ‘phase 7’, the easing of restriction measures; ‘phase 8’, the removal of legal limits on social contact and reopening of all closed sectors; ‘phase 9’, the reintroduction of ‘Plan B’ measures to limit the spread of the emerging Omicron variant in December 2021; and ‘phase 10’, the removal of all restrictions as part of the UK’s ‘Living with COVID-19’ strategy ([14]; Supplementary Table S1). Phases were based on nationwide policy and did not account for regional or local differences in restriction measures implemented as part of England’s tier system [14].

Figure 1. Data covering the period between January 2020 and May 2021 split into 10 pandemic phases showing A) Laboratory confirmed COVID-19 cases in England reported via the UK COVID-19 dashboard (https://coronavirus.data.gov.uk/) (B) Gastrointestinal outbreaks reported to the UK Health Security Agency (UKHSA) and entered into HPZone by week of date recorded during the pandemic period (red line) and 5-year historic average and associated 95% confidence interval (blue line) and C) Laboratory confirmed gastrointestinal infections* reported to the UKHSA by specimen date during the pandemic period (red line) and 5-year historic average and associated 95% confidence interval (green line). Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response.This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place during early January 2020.

* Laboratory confirmed gastrointestinal infections (Campylobacter spp., Cryptosporidium spp., Shiga-toxin producing E. coli [STEC], Giardia sp., Norovirus, non-typhoidal Salmonella spp., Shigellaspp), reported by NHS laboratories to UKHSA’s SGSS laboratory surveillance system.

Cumulative weekly outbreaks recorded in HPZone and pseudonymised SGSS data for selected laboratory-confirmed organisms (Campylobacter spp., Cryptosporidium spp., Shiga toxin-producing Escherichia coli (E. coli) [STEC], Giardia sp., Listeria spp., Norovirus, non-typhoidal Salmonella spp., and Shigella spp.) were grouped by a week of notification date (HPZone) or specimen date (SGSS).

Outbreak and laboratory data from the pandemic period were plotted in a time series together with the weekly 5-year average and 95% confidence intervals (2015–2019) and superimposed COVID-19 outbreak phases, unless otherwise specified. Syndromic data were analysed as described elsewhere [Reference Bawa, Elliot, Morbey, Ladhani, Cunliffe, O’Brien, Regan and Smith15]. Daily incidence rates per 100,000 attendances or patient contacts were calculated using a denominator of number of people using or contacting each service each day for all health conditions and a numerator of diarrhoea and/or vomiting or gastroenteritis, with 7-day moving averages determined. The same period in 2019 was used as a comparator for 2020 to 2022. Established syndromic surveillance data were complemented by Google Trends data, as web searches are unlikely to be as impacted as healthcare services by capacity issues [Reference Jördens, Loosen, Seraphin, Luedde, Kostev and Roderburg8]. Google Trends searches were performed for key phrases associated with GI illness in England, as described previously, with a score of 100, which is used to represent relative search interest over the given time period and geography. Analyses were in RStudio, PBC, Boston, MA (version 2022.7.1.554).

Ethical approval was not required for this study as data collection is conducted as part of the routine surveillance of communicable diseases under the provisions of Section 251 of the NHS Act 2006 and therefore does not require individual patient consent. The study was reviewed by the UKHSA Research Ethics and Governance Group and was found to be fully compliant with all regulatory requirements.

Results

Outbreak activity

GI outbreak activity decreased during the first lockdown with activity remaining significantly lower than historic figures despite the easing of measures from June 2020 (phase 4; Figure 1b). Indeed, outbreak activity remained below expected for 2020 and into the 2020/21 winter season where a 92% reduction in reported outbreaks was observed (November 2020–March 2021; phase 6; 208 versus 2,484 outbreaks (95% CI: 1,902–3,106)). Low outbreak activity over the 2020/21 winter season coincided with England’s second and third national lockdowns during phase 6 (31 October–2 December and 4 January 2021–8 March 2021). GI outbreaks reported in England are predominantly viral in nature occurring within health and social care settings, particularly from October to April [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3].

Outbreak activity began to gradually increase from March 2021 as lockdown restriction measures were gradually lifted (phase 7), returning to normal limits or higher between June and October 2021 (weeks 24–43; phases 7 and 8), before decreasing with the implementation of ‘Plan B’ measures in response to the emergence of the new Omicron variant in December 2021 (December 2021–February 2022; phase 9; 48% reduction; 844 versus 1,614 outbreaks (95% CI: 1,294–1,935)). With the removal of all restriction measures as part of the UK Government’s ‘Living with COVID’ strategy, outbreak activity increased to the highest level seen during the study period, though remained within historic limits in phase 10 (March–April 2022).

Reductions in suspected and confirmed viral, protozoal, and bacterial outbreaks were observed across the pandemic period (phases 2–9), with a 58% reduction in the number of reported suspected and confirmed viral outbreaks (3,946 versus 9,376 outbreaks), a 90% reduction in protozoal outbreaks (14 versus 142), and a 41% reduction in bacterial outbreaks (244 versus 414 outbreaks; 41% decrease) reported.

Laboratory surveillance

Following initial decreases, cases of laboratory-confirmed GI pathogens began to increase during the first lockdown (phase 3; Figure 1c) but remained significantly lower than historic values for 2020 (68,394 versus 82,063 cases (95% CI: 77,437–86,689)), although small peaks in activity were observed in phase 4 (July–September 2020). During the second and third UK lockdowns (phase 6; November 2020–March 2021), laboratory-confirmed cases did not decrease to the same extent as the first lockdown, although activity remained lower than historically observed (23% decrease; 18,726 versus 24,407 (95% CI: 23,243–25,570)). Cases returned to just under expected limits with the easing of restriction measures in March 2021 (phase 7) and remained 15% below historic figures until January 2022 when activity returned to within normal limits.

Cumulative GI trends are strongly influenced by Campylobacter activity, the most common pathogen diagnosed by diagnostic laboratories in England. Therefore, we determined the trend for each GI pathogen separately across the pandemic period (phases 2–9; Figure 2). Listeria (not shown in Figure 2 due to small numbers) and STEC activity quickly returned to expected levels from May 2020 with the easing of lockdown measures, while Campylobacter diagnoses returned to normal in November 2020 (phase 6). Diagnoses of these pathogens then remained comparable to or higher than historic figures for the remainder of the pandemic period (STEC: 9% increase over the pandemic period; 2,366 versus 2,175 cases (95% CI: 1,514–2,823 cases); Listeria spp.: 15% increase: 379 versus 330 (95% CI: 145–514); and Campylobacter spp.: 6% decrease: 104,668 versus 111,452 (95% CI: 100,592–121,050)). In comparison, reports of laboratory-confirmed Cryptosporidium (52% decrease: 4,629 versus 9,547 (95% CI: 7,501–11,482)), Giardia (48% decrease: 5,046 versus 9,769 (95% CI: 8,440–11,003)), Shigella (41% decrease: 2,810 versus 4,781 (95% CI: 3,442–6,064)), and Salmonella (42% decrease: 10,644 versus 18,353 (95% CI: 16,337–20,188)) remained substantially lower than historic figures across the pandemic period, with activity for all bacterial and parasitic pathogens with the exception of giardia returning to within or above expected figures in early 2022.

Figure 2. Data covering the period between January 2020 and May 2021 split into 10 pandemic phases showing laboratory confirmed gastrointestinal pathogens* reported to UKHSA by specimen date during the pandemic period (red line) and 5-year historic average and associated 95% confidence interval (green line) for Campylobacter, Cryptosporidium, Giardia, Norovirus, Salmonella, Shigella and STEC**. Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures inplace.

*Laboratory confirmed gastrointestinal infections (Campylobacter spp., Cryptosporidium spp., Shiga-toxin producing E. coli [STEC], Giardia sp., Norovirus, non-typhoidal Salmonella spp., Shigella spp), reported by NHS laboratories to UKHSA’s SGSS laboratory surveillance system

** Listeria is not included in Figure 2 due to suppression of small numbers.

Norovirus activity remained lower than expected for 2020 and into the 2020/21 winter season. Activity then increased in May 2021 (phase 7), corresponding with the easing of restriction measures and reopening of schools and nurseries. Unusually, high norovirus activity continued throughout the summer of 2021 exceeding the 5-year average over a 2-month period in August and September before plateauing in the winter of 2021/22, which coincided with the emergence of the Omicron COVID-19 variant. Across the pandemic period, cases were lower than expected based on historic figures (66% decrease: 5,030 versus 14,798 cases (95% CI: 10,843–18,567)).

Syndromic surveillance

Syndromic surveillance data were used to determine healthcare utilisation for gastroenteritis or diarrhoea and vomiting combined across several syndromic indicators. Following initial decreases across all indicators during the first lockdown, emergency department (ED) attendances returned to 2019 levels during the easing of lockdown measures in both 2020 (phase 4) and 2021 (phase 7) but remained below historic figures across the 2020/21 winter season (Figure 3a). Interestingly, while GP out-of-hours (Figure 3b) and GP in-hours (Figure 3c) consultations remained lower than in 2019, despite small increases in July 2021, which coincided with the easing of measures, there were increases in ED attendances above what would be expected based on 2019 data. NHS 111 calls for diarrhoea and vomiting showed a similar trend to other syndromic systems (Figure 3d), with a decrease in activity before the first lockdown, a low number of calls across the pandemic period, and an increase in activity with the easing of measures in mid-2021. Established syndromic surveillance data were complemented by Google Trends data, with searches for the terms ‘Sickness bug’, ‘Gastroenteritis’, and ‘Food poisoning’ again showing low activity across the pandemic period until the easing of restriction measures in mid-2021 (Figure 4).

Figure 3. Data split into 10 pandemic phases showing A) emergency department attendances B) GP out of hours contacts C) GP in hours consultations and D) NHS111 calls. For emergency department, GP out of hours and GP in hours indicators show both the pandemic period and historic 2019 comparator, with the rolling 7-day average rate per 100,000 attendances for the pandemic period indicated in red and the historic comparator in blue. NHS111 calls show combined calls for diarrhoea and vomiting with the rolling 7-day average rate per 100,000 calls for the pandemic period indicated in red and the historic 2019 comparator in green. Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place. Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; ancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place.

Figure 4. Relative search volume for the Google search terms A) Sickness bug, B) Gastroenteritis and C) Food poisoning determined using Google Trend data restricted to England for the pandemic period (red line) and 2019 (green line).Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place.

Discussion

There is increasing evidence that NPIs and health system changes introduced during the COVID-19 pandemic in early 2020 led to reductions in communicable infections, including enteric pathogens [Reference Bruggink, Garcia-Clapes, Tran, Druce and Thorley4-Reference Kraay, Han, Kambhampati, Wikswo, Mirza and Lopman10]. The drivers of change were hypothesised to be multifactorial; changes to health-seeking behaviour, pressure on diagnostic services, and surveillance system ascertainment have undoubtedly all played a role; however, there has likely been a true decrease in the incidence of infections resulting from the control measures and restrictions implemented. Here, through the triangulation of several national surveillance systems, we provide further evidence to support the hypothesis of a true decrease in the incidence of certain GI pathogens by describing GI infection trends in England during the entirety of COVID-19 NPIs and restrictions up to the removal of all restrictions in April 2022.

We show that following the end of phase 3, the first lockdown in 2020, the activity of foodborne pathogens such as STEC and Campylobacter quickly returned to historic levels, while pathogens more associated with person-to-person transmission or foreign travel (and therefore more influenced by hand hygiene, social distancing measures, and travel regulations) recovered at a slower rate [Reference Hawker, Begg, Blair, Reintjes and Weinberg1]. These findings suggest that although rapid changes to healthcare provision altered health-seeking behaviour and non-COVID-19 testing capacity likely resulted in initial decreases observed across surveillance systems [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3], there were true pathogen-specific reductions in incidence as a result of implemented measures.

Across the pandemic period, the activity of enteric pathogens correlated with stages in the COVID-19 response. Periods of higher pathogen activity corresponded to the relaxation of initial NPIs and lower activity identified with the reimplementation of further control measures with subsequent COVID-19 waves. This was particularly striking for norovirus, where the reimplementation of further measures in the 2020/21 and 2021/22 winter seasons was followed by substantially lower laboratory-confirmed and outbreak activity than expected, while increased out-of-season activity followed the easing of measures in the summer of 2021.

Increases in GI activity following the relaxation of NPIs were also observed in surveillance data from other countries. As in England, unseasonal activity of norovirus occurred in Germany in the summer and Autumn of 2021, following the relaxation of measures [Reference Maison, Peck, Illi, Meyer-Buehn, von Mutius, Hübner and von Both16-Reference Douglas, Sandmann, Allen, Celma, Beard and Larkin17], with the same trend also observed for several respiratory viruses [Reference Maison, Peck, Illi, Meyer-Buehn, von Mutius, Hübner and von Both16]. Furthermore, data from Australia showed that the removal of NPIs coincided with an increase in gastroenteritis outbreaks in childcare settings [Reference Bruggink, Garcia-Clapes, Tran, Druce and Thorley4]. Reductions in viral GI pathogen activity also coincided with decreases in outbreak number and average outbreak size [Reference Kraay, Han, Kambhampati, Wikswo, Mirza and Lopman10] and reductions in both the number of enteric samples submitted and the proportion of positive samples [Reference Eigner, Verstraeten and Weil5]. In the UK, most reported viral outbreaks are linked to health and social care settings [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3]; therefore, some of the reduction observed is likely due to restricted access to and restricted movement within such settings in addition to enhanced hygiene measures.

The differing trends observed for a diverse range of enteric pathogens provide support to the hypothesis of a true decrease in incidence with differences between pathogens also observed in laboratory surveillance systems in Korea, China, Germany, and Poland [Reference Ahn, Park, Lim, Chae, Yun, Lee, Kim, Choi and Yi6, Reference Grochowska, Ambrozej, Wachnik, Demkow, Podsiadly and Feleszko7, Reference Kim, Kim, Choi and Park18-Reference Mack, Gohl, Kolbert, Schui, Küsters, Harzer, Pum and Zöllner20]. These studies showed that bacterial pathogens were non-significantly different from historic figures over the 2020 period, but viral pathogens were significantly reduced. The differences observed are likely due to the varied modes of transmission between pathogens. Viral pathogens are more likely to be transmitted from person to person, while bacterial pathogens are more commonly transmitted via foodborne routes. The setting of ‘acquisition of infection’ also differs between viral and bacterial pathogens, with viral pathogens frequently associated with closed settings such as schools, care homes, and hospitals or with food premises, while bacterial pathogens are often acquired from food products consumed within the home. An earlier study from England found a stronger association between norovirus activity and changes in the stringency of COVID-19 control measures than that for Campylobacter [Reference Ondrikova, Clough, Douglas, Iturriza-Gomara, Larkin, Vivancos, Harris and Cunliffe21]. Foreign travel is an important risk factor for many bacterial pathogens in England [Reference Hawker, Begg, Blair, Reintjes and Weinberg1,Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3]. Here, we show that while diagnoses of certain bacterial pathogens returned to normal in England, as in other countries, other pathogens such as Salmonella remained lower than historic figures for 2020/2021. This was comparable to findings from the USA where both bacterial and viral gastrointestinal pathogens were reduced [Reference Kim, Kim, Choi and Park18] and likely reflect the impact that restrictions on non-essential foreign travel have had on organisms for which foreign travel is an important risk factor [Reference Hawker, Begg, Blair, Reintjes and Weinberg1,Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3].

While there may be a true difference in the incidence of bacterial and viral pathogens resulting from differences in transmission mechanism, it is also possible that changes in healthcare-seeking behaviour, differing presentations, and the management of laboratory testing for pathogens may have contributed to the changing trends observed. It has previously been suggested that changes observed in laboratory reporting surveillance data in 2020 were due to underreporting because of reduced testing capacity [Reference Ondrikova, Clough, Douglas, Iturriza-Gomara, Larkin, Vivancos, Harris and Cunliffe21, Reference Chan22]; however, core national laboratory capacity was not used to support mass public SARS-CoV-2 testing from May 2020, which will have minimised the impact on laboratory capacity for non-COVID-19 testing during the remainder of the pandemic [23]. Further consideration must be made of the reduced capacity available to the wider public health system and changes to healthcare-seeking behaviour resulting in fewer samples being submitted for testing. It is also important to note that changes to laboratory processing and ascertainment cannot explain the impacts observed across non-laboratory systems such as syndromic surveillance systems. Although healthcare systems used for syndromic surveillance may be impacted by reduced availability of healthcare services, Google Trends web search data are unlikely to be impacted by such capacity issues and showed a similar trend to more formal syndromic surveillance systems. It is also possible that individuals with more severe and prolonged infections such as STEC, which tend to be bacterial, were more likely to access care or that bloody diarrhoea specimens were prioritised for testing [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3, Reference Ondrikova, Clough, Douglas, Iturriza-Gomara, Larkin, Vivancos, Harris and Cunliffe21]. Syndromic surveillance data indeed suggest that ED attendances for GI attendances returned to normal levels more rapidly than GP in- and out-of-hours attendances, despite lower than usual ED attendances being observed over the 2020/21 and 2021/22 winter periods. This may reflect changes to health-seeking behaviour or may indicate changes to provision or issues with healthcare access. Many syndromic indicators, such as those for non-infectious gastrointestinal conditions, rapidly returned to baseline levels towards the end of the first UK lockdown, while gastrointestinal infections showed more modest increases [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3]. NHS 111 call data and Google Trends are less likely to be impacted by healthcare capacity issues or health system changes. Both systems showed similar trends to those observed in other national surveillance systems, with reductions in activity observed until the lifting of control measures in the summer of 2021.

It is perhaps unsurprising that a true decrease in GI pathogen activity is likely to have occurred in England as many of the control measures implemented during the COVID-19 response are similar to those that would be implemented in response to a GI outbreak. Indeed, evidence suggests that NPIs implemented in the response were associated with reductions in other pathogens, such as influenza and respiratory syncytial virus [Reference Sullivan, Carlson, Cheng, Chilver, Dwyer, Irwin, Kok, Macartney, MacLachlan, Minney-Smith, Smith, Stocks, Taylor and Barr24-Reference Bardsley, Morbey, Hughes, Beck, Watson, Zhao, Ellis, Smith and Elliot27]. Messaging around hand hygiene and physical distancing were consistent across the pandemic period with good adherence reported [Reference Fancourt, Bu, Mak Wan and Steptoe28-Reference Cowling, Ali, Ng, Tsang, Li, Fong, Liao, Kwan, Lee, Chiu, Wu, Wu and Leung29], and this has likely reduced person-to-person transmission of pathogens. The closure of schools and other settings has likely also led to a reduction in person-to-person transmission, while the closure of food premises and restrictions on mass gatherings and catered events have also probably reduced the risks associated with foodborne illness. Indeed, two peaks in activity were observed in the summer of 2020, corresponding to the reopening of restaurants to dine-in customers and England’s ‘Eat Out to Help Out’ scheme, respectively [30]. These findings are good evidence for the effectiveness of simple infection control measures such as hand washing and should strengthen the rationale for continuing public health campaigns aimed at reducing the spread of infectious diseases.

This study was strengthened by the triangulation of data from several national and regional-based surveillance systems; using this approach, we could determine that the trends observed were consistent across all indicators and show the importance of multiple surveillance systems to allow for comparative analysis across multiple indicators. However, this study is not comprehensive and there are other examples of operational surveillance systems, which have not been included in this work due to their limitations [Reference Love, Elliot, Chalmers, Douglas, Gharbia, McCormick, Hughes, Morbey, Oliver, Vivancos and Smith3]. An additional limitation of this study is that negative laboratory test results are not captured by the SGSS laboratory surveillance system; therefore, it was not possible to determine to what degree the changes were due to changes in testing – we were also unable to calculate the positivity rate to assess whether only severe cases were being tested. As this study uses an ecological design, control measures implemented during the COVID-19 response cannot be proven to be the sole cause of changes in GI pathogen activity. Furthermore, the study does not take into account the geographical variation introduced by local or regional restriction measures, such as the three-tier system implemented between October 2020 and January 2021 whereby local authorities had different levels of restrictions [Reference Scott31], which would help to strengthen the relationship between control measures and GI pathogen activity.

This work is limited to describing trends in GI infections, and while it does not directly look at the drivers of this change, it does provide an indirect assessment. There is therefore scope for further research into the trends observed, for example, by performing in-depth pathogen-specific analyses to look for potential drivers such as socioeconomic factors and reduced foreign travel, which may have resulted in the trends observed.

Supplementary material

The supplementary material for this article can be found at http://doi.org/10.1017/S095026882300136X.

Data availability statement

No additional data are available.

Acknowledgements

The authors acknowledge the contribution and support from all data providers including NHS 111 and NHS Digital; QSurveillance, University of Oxford, EMIS/EMIS practices, ClinRisk, TPP, ResearchOne, and participating SystmOne GP practices; Advanced and the participating OOH service providers; participating EDSSS emergency departments, Royal College of Emergency Medicine; North East, North West, Yorkshire, East Midlands, West Midlands, East of England, London, South East Coast, South Central, and South Western NHS Ambulance Trusts; and the Association of Ambulance Chief Executives. The authors also wish to thank Ian Fawcett and Aryan Nikhab for their technical support.

Author contribution

N.K.L., S.G., I.O, and G.E.S. designed the study. N.K.L. analysed the data, with support from A.D., S.G., H.H., R.M., G.E.S., and A.J.E. contributed to the interpretation of the results. N.K.L. and A.J.E. wrote the manuscript with input from all authors.

Financial support

N.K.L., H.H., R.M., G.E.S., and A.J.E. receive support from the National Institute for Health Research Health Protection Research Unit (NIHR HPRU) in Gastrointestinal Infections, and IO receives support from the NIHR HPRU in Behavioural Science and Evaluation. R.M., G.E.S., and A.J.E. receive support from the NIHR HPRU in Emergency Preparedness and Response. The views expressed are those of the author(s) and not necessarily those of the NIHR, UK Health Security Agency, or the Department of Health and Social Care. Funding was not applicable to this study.

Competing interest

The authors declare none.

Ethical standard

This study was conducted under the provisions of Section 251 of the NHS Act 2006 and therefore did not require individual patient consent. The study was reviewed by the UKHSA Research Ethics and Governance Group and was found to be fully compliant with all regulatory requirements. As no regulatory or ethical issues were identified, the study was approved. The authors affirm that the manuscript is an honest, accurate, and transparent account of the study being reported; that no important aspects of the study have been omitted; and that any discrepancies from the study as originally planned have been explained.

References

Hawker, J, Begg, N, Blair, I, Reintjes, R and Weinberg, J (2005) Communicable Disease Control Handbook, 2nd Edn. Oxford, England: Blackwell Publishing.CrossRefGoogle Scholar
Tam, CC, Rodrigues, LC, Viviani, L, Dodds, JP, Evans, MR, Hunter, PR, Gray, J, Letley, LH, Rait, G, Tompkins, DS and O’Brien, SJ (2012) Longitudinal study of infectious intestinal disease in the UK (IID2 study): Incidence in the community and presenting to general practice. Gut 61(1), 69.CrossRefGoogle ScholarPubMed
Love, NK, Elliot, A, Chalmers, R, Douglas, A, Gharbia, S, McCormick, J, Hughes, H, Morbey, R, Oliver, I, Vivancos, R and Smith, G (2022) Impact of the COVID-19 pandemic on gastrointestinal infection trends in England, February-July 2020. BMJ Open 12(3), e050469.CrossRefGoogle ScholarPubMed
Bruggink, LD, Garcia-Clapes, A, Tran, T, Druce, JD and Thorley, BR (2018) Decreased incidence of enterovirus and norovirus infections during the COVID-19 pandemic, Victoria, Australia, 2020. Communicable Disease Intelligence 45. 29 January 2021. https://doi.org/10.33321/cdi.2021.45.5. PMID: 33573536.Google Scholar
Eigner, U, Verstraeten, T and Weil, J (2021) Decrease in norovirus infections in Germany following COVID-19 containment measures. Journal of Infection 82, 276316.CrossRefGoogle ScholarPubMed
Ahn, SY, Park, JY, Lim, IS, Chae, SA, Yun, SW, Lee, NM, Kim, SY, Choi, BS and Yi, DY (2021) Changes in the occurrence of gastrointestinal infections after COVID-19 in Korea. Journal of Korean Medical Science 36(24), e180.CrossRefGoogle ScholarPubMed
Grochowska, M, Ambrozej, D, Wachnik, A, Demkow, U, Podsiadly, E and Feleszko, W (2022) The impact of the COVID-19 pandemic lockdown on pediatric infections-a single-center retrospective study. Microorganisms 10(1), 178.CrossRefGoogle ScholarPubMed
Jördens, MS, Loosen, SH, Seraphin, T, Luedde, T, Kostev, K and Roderburg, C (2021) Impact of the COVID-19 pandemic on consultations and diagnoses in gastroenterology practices in Germany. Frontiers in Medicine (Lausanne) 8, 684032.CrossRefGoogle ScholarPubMed
Tanislav, C and Kostev, K (2021) Investigation of the prevalence of non-COVID-19 infectious diseases during the COVID-19 pandemic. Public Health 203, 5357.CrossRefGoogle ScholarPubMed
Kraay, ANM, Han, P, Kambhampati, AK, Wikswo, ME, Mirza, SA and Lopman, BA (2021) Impact of nonpharmaceutical interventions for severe acute respiratory syndrome coronavirus 2 on norovirus outbreaks: An analysis of outbreaks reported by 9 US states. The Journal of Infectious Diseases 224(1), 913.CrossRefGoogle ScholarPubMed
Kara-Zaïtri, C, Gelletlie, R and Schweiger, M (2012) The development and deployment of a national web-based system for communicable disease control in England. International Journal of Infectious Diseases 16, e133.CrossRefGoogle Scholar
Smith, GE, Elliot, AJ, Lake, I, Edeghere, O, Morbey, R, Catchpole, M, Heymann, DL, Hawker, J, Ibbotson, S, McCloskey, B and Pebody, R (2019) Syndromic surveillance: Two decades experience of sustainable systems - Its people not just data! Epidemiology & Infection 147, e101. https://doi.org/10.1017/S0950268819000074CrossRefGoogle Scholar
Mathieu, E, Ritchie, H, Rodés-Guirao, L, Appel, C, Giattino, C, Hasell, J, Macdonald, B, Dattani, S,Beltekian, D, Ortiz-Ospina, E and Roser, M (2020) Coronavirus Pandemic (COVID-19). Published online at OurWorldInData.org. Retrieved from: COVID-19: Stringency Index - Our World in Data.Google Scholar
Institute for Government. UK government coronavirus decision making: key phases. Available at UK government coronavirus decision making: key phases | The Institute for Government (accessed 30 August 2022).Google Scholar
Bawa, Z, Elliot, AJ, Morbey, RA, Ladhani, S, Cunliffe, NA, O’Brien, SJ, Regan, M and Smith, GE (2015) Assessing the likely impact of a rotavirus vaccination program in England: The contribution of syndromic surveillance. Clinical Infectious Diseases 61(1), 7785. https://doi.org/10.1093/cid/civ264CrossRefGoogle ScholarPubMed
Maison, N, Peck, A, Illi, S, Meyer-Buehn, M, von Mutius, E, Hübner, J and von Both, U (2022). The rising of old foes: Impact of lockdown periods on “non-SARS-CoV-2” viral respiratory and gastrointestinal infections. Infection 50(2), 519524. https://doi.org/10.1007/s15010-022-01756-4CrossRefGoogle ScholarPubMed
Douglas, A, Sandmann, FG, Allen, DJ, Celma, CC, Beard, S and Larkin, L (2021) Impact of COVID-19 on national surveillance of norovirus in England and potential risk of increased disease activity in 2021. Journal of Hospital Infection 112, 124126.CrossRefGoogle ScholarPubMed
Kim, S, Kim, J, Choi, BY and Park, B (2022) Trends in gastrointestinal infections before and during nonpharmaceutical interventions in Korea in comparison with the United States. Epidemiology and Health 44, e2022011.CrossRefGoogle ScholarPubMed
Wang, LP, Han, JY, Zhou, SX, Yu, LJ, Lu, QB, Zhang, XA, Zhang, HY, Ren, X, Zhang, CH, Wang, YF, Lin, SH, Xu, Q, Jiang, BG, Lv, CL, Chen, JJ, Li, CJ, Li, ZJ, Yang, Y, Liu, W, Fang, LQ, Hay, SI, Gao, GF and Yang, WZ (2021) Chinese Centers for Disease Control and Prevention (CDC) etiology of diarrhea surveillance study team. The changing pattern of enteric pathogen infections in China during the COVID-19 pandemic: A nation-wide observational study. The Lancet Regional Health – Western Pacific 16, 100268.CrossRefGoogle Scholar
Mack, D, Gohl, P, Kolbert, M, Schui, D, Küsters, U, Harzer, O, Pum, J and Zöllner, B (2021) Where have the enteric viruses gone? - Differential effects on frequent causes of infectious diarrhoea by SARS-CoV-2 pandemic lockdown measures. Infection Prevention in Practice 3(4), 100184.CrossRefGoogle ScholarPubMed
Ondrikova, N, Clough, HE, Douglas, A, Iturriza-Gomara, M, Larkin, L, Vivancos, R, Harris, JP and Cunliffe, NA (2021) Differential impact of the COVID-19 pandemic on laboratory reporting of norovirus and campylobacter in England: A modelling approach. PLoS ONE [Electronic Resource] 16(8), e0256638.CrossRefGoogle Scholar
Chan, MC (2022) Return of norovirus and rotavirus activity in winter 202021 in City with strict COVID-19 control strategy, Hong Kong, China. Emerging Infectious Diseases 28(3), 713716.CrossRefGoogle Scholar
UK Health Security Agency NHS Test and Trace: How we test your samples. Available at NHS Test and Trace: how we test your samples - GOV.UK (www.gov.uk) (accessed 30 August 2022).Google Scholar
Sullivan, SGCarlson, SCheng, ACChilver, MBNDwyer, DEIrwin, MKok, JMacartney, KMacLachlan, JMinney-Smith, CSmith, DStocks, NTaylor, J and Barr, IG (2020) Where has all the influenza gone? The impact of COVID-19 on the circulation of influenza and other respiratory viruses, Australia, march to September 2020Eurosurveillance 25(47), 2001847.CrossRefGoogle Scholar
Itaya, T, Furuse, Y and Jindai, K (2020) Does COVID-19 infection impact on the trend of seasonal influenza infection? 11 countries and regions, from 2014 to 2020. International Journal of Infectious Diseases 97, 7880. https://doi.org/10.1016/j.ijid.2020.05.088CrossRefGoogle ScholarPubMed
Melidou, A, Pereyaslov, D, Hungnes, O, Prosenc, K, Alm, E, Adlhoch, C, Fielding, J, Sneiderman, M, Martinuka, O, Celentano, LP and Pebody, R (2020 ) Virological surveillance of influenza viruses in the WHO European region in 2019/20 – Impact of the COVID-19 pandemic. Eurosurveillance 25(46), 2001822. https://doi.org/10.2807/1560-7917.ES.2020.25.46.2001822CrossRefGoogle Scholar
Bardsley, M, Morbey, RA, Hughes, HE, Beck, CR, Watson, CH, Zhao, H, Ellis, J, Smith, GE and Elliot, AJ (2023 ) Epidemiology of respiratory syncytial virus in children younger than 5 years in England during the COVID-19 pandemic, measured by laboratory, clinical, and syndromic surveillance: A retrospective observational study. The Lancet Infectious Diseases 23(1), 5666. https://doi.org/10.1016/S1473-3099(22)00525-4CrossRefGoogle ScholarPubMed
Fancourt, D, Bu, F, Mak Wan, H and Steptoe, A (2020) Covid-19 Social Study: Results Release 17. Available at REPORTS | COVID Social Study (accessed 15 August 2023).Google Scholar
Cowling, BJ, Ali, ST, Ng, TWY, Tsang, TK, Li, JCM, Fong, MW, Liao, Q, Kwan, MY, Lee, SL, Chiu, SS, Wu, JT, Wu, P and Leung, GM (2020) Impact assessment of non-pharmaceutical interventions against coronavirus disease 2019 and influenza in Hong Kong: An observational study. The Lancet Public Health 5(5), e279e288. https://doi.org/10.1016/S2468-2667(20)30090-6CrossRefGoogle Scholar
HM Reenue & Customs Get a discount with the Eat Out to Help Out Scheme. Available at [Withdrawn] Get a discount with the Eat Out to Help Out Scheme - GOV.UK (www.gov.uk) (accessed 30 August 2022).Google Scholar
Scott, E Covid-19 local alert levels: Three-tier system for England. Available at Covid-19 local alert levels: Three-tier system for England - House of Lords Library (parliament.uk) (accessed 2 May 2023).Google Scholar
Figure 0

Figure 1. Data covering the period between January 2020 and May 2021 split into 10 pandemic phases showing A) Laboratory confirmed COVID-19 cases in England reported via the UK COVID-19 dashboard (https://coronavirus.data.gov.uk/) (B) Gastrointestinal outbreaks reported to the UK Health Security Agency (UKHSA) and entered into HPZone by week of date recorded during the pandemic period (red line) and 5-year historic average and associated 95% confidence interval (blue line) and C) Laboratory confirmed gastrointestinal infections* reported to the UKHSA by specimen date during the pandemic period (red line) and 5-year historic average and associated 95% confidence interval (green line). Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response.This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place during early January 2020.* Laboratory confirmed gastrointestinal infections (Campylobacter spp., Cryptosporidium spp., Shiga-toxin producing E. coli [STEC], Giardia sp., Norovirus, non-typhoidal Salmonella spp., Shigellaspp), reported by NHS laboratories to UKHSA’s SGSS laboratory surveillance system.

Figure 1

Figure 2. Data covering the period between January 2020 and May 2021 split into 10 pandemic phases showing laboratory confirmed gastrointestinal pathogens* reported to UKHSA by specimen date during the pandemic period (red line) and 5-year historic average and associated 95% confidence interval (green line) for Campylobacter, Cryptosporidium, Giardia, Norovirus, Salmonella, Shigella and STEC**. Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures inplace.*Laboratory confirmed gastrointestinal infections (Campylobacter spp., Cryptosporidium spp., Shiga-toxin producing E. coli [STEC], Giardia sp., Norovirus, non-typhoidal Salmonella spp., Shigella spp), reported by NHS laboratories to UKHSA’s SGSS laboratory surveillance system** Listeria is not included in Figure 2 due to suppression of small numbers.

Figure 2

Figure 3. Data split into 10 pandemic phases showing A) emergency department attendances B) GP out of hours contacts C) GP in hours consultations and D) NHS111 calls. For emergency department, GP out of hours and GP in hours indicators show both the pandemic period and historic 2019 comparator, with the rolling 7-day average rate per 100,000 attendances for the pandemic period indicated in red and the historic comparator in blue. NHS111 calls show combined calls for diarrhoea and vomiting with the rolling 7-day average rate per 100,000 calls for the pandemic period indicated in red and the historic 2019 comparator in green. Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place. Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; ancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place.

Figure 3

Figure 4. Relative search volume for the Google search terms A) Sickness bug, B) Gastroenteritis and C) Food poisoning determined using Google Trend data restricted to England for the pandemic period (red line) and 2019 (green line).Pandemic phases are assigned based on control measures implemented during the pandemic response, using the Oxford Stringency Index which indicates the severity of government restrictions in England [13] from least severe measures to most severe measures. A weekly stringency index was calculated based on the mean score of nine metrics: school closures; workplace closures; cancellation of public events; restrictions on public gatherings; closures of public transport; stay-at-home requirements; public information campaigns; restrictions on internal movements; and international travel control, each taking a value between 0 and 100, with 100 being the strictest response. This score was converted to deciles, as displayed in the bar at the top of the figure. Grey shaded area indicates no restriction measures in place.

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