Ethics approval and consent

Virus Watch was approved by the Hampstead NHS Health Research Authority Ethics Committee: 20/HRA/2320, and conformed to the ethical standards set out in the Declaration of Helsinki. All participants provided informed consent for all aspects of the study.

Participants

Participants (n = 5,630) were a subset of the Virus Watch longitudinal cohort study (n = 58,628). Virus Watch is a community prospective cohort study established in June 2020 and investigates acute infection syndromes and SARS-CoV-2 infections in households across England and Wales. The study involves weekly questionnaires about symptoms, SARS-CoV-2 testing, and vaccinations, as well as bespoke monthly questionnaires investigating demographic, clinical and psychosocial topics relevant to COVID-19 that are beyond the scope of the weekly survey. These monthly surveys include a repeated survey related to new-onset long-term symptoms.

Households were recruited into the Virus Watch study using SMS and postal recruitment supported by general practices and using social media campaigns. Eligibility criteria were residence in England or Wales, household size up to six people (due to survey infrastructure limitations), internet and email access, ability to complete surveys in English, and consent or assent from all household members. Further detail of recruitment and methodology are provided in the study protocol [Reference Hayward, Fragaszy, Kovar, Nguyen, Beale and Byrne26] and cohort profile [Reference Byrne, Kovar, Beale, Braithwaite, Fragaszy, Fong, Geismar, Hoskins, Navaratnam, Nguyen and Patel27] and recruitment dates are illustrated in Supplementary Figure S1. Participants in the current long-term symptoms study comprised Virus Watch participants who met the following further inclusion criteria:

1. 1. resident in England, due to data availability around variant periods,

2. 2. responded to monthly survey(s) related to new-onset long-term symptoms covering the period between February 2020 and March 2023,

3. 3. able to be assigned infection status during variant dominance periods based on SARS-CoV-2 clinical testing records from linkage and study data.

Exposure

The exposure of interest was SARS-CoV-2 variant dominance period, with the exposure stratified by infection status (SARS-CoV-2 infection, other ARI, or no infection; see Statistical Analyses for further description). Variant dominance periods were derived based on date and national region using previously established methodology [Reference Geismar, Fragaszy, Nguyen, Fong, Shrotri and Beale28], with dominance periods defined by the date limits between which over 75% of SARS-CoV-2 infections within each of England’s nine national regions were attributed to each variant based on UK Health Security Agency national surveillance [29, 30]. The following dominance periods were included during the study period: Wild Type, Alpha, Delta, Omicron BA.1, Omicron BA.2, Omicron BA.5, and Omicron Other, that is, time during the overall Omicron dominance period where multiple sub-lineages circulated and none were dominant. Please see Supplementary Table S1 for variant period dates.

Infection status during each period was classified using linkage to SARS-CoV-2 test results from UK national records, study-based testing, and self-reported information about testing and acute illness episodes provided in the weekly survey, with detail for each infection status provided below.

Outcome

The outcome was binary development of new-onset long-term symptoms (yes/no long-term symptoms), with the data items used to derive the binary outcome described below. As SARS-CoV-2 was the primary focus of this analysis, the definition of long-term symptoms was derived from the World Health Organization consensus definition for PCC: onset of symptoms lasting at least 2 months within 3 months of acute infection, which cannot be explained by another diagnosis [31]. Participants were included in this group if at least one symptom was present for at least 2 months, regardless of the duration of other symptoms. Participants were not included in this analysis if all of their symptoms had occurred for less than 2 months as they did not meet our long-term symptom definition derived from WHO criteria for PCC, but they may also be clinically distinct from people with no post-acute sequelae. Where there was no acute infection present (i.e., the ‘no infection’ exposure group), the requirement for symptoms developing within 3 months of an infection was removed but other criteria remained the same. Participants were classified as not having long-term sequelae if they completed all surveys – to prevent non-detection of unreported symptoms and consequently misclassification – and never reported new-onset long-term symptoms at any point during the study period.

Data were drawn from a survey regarding new-onset long-term symptoms sent to the Virus Watch cohort. The survey requested participants to indicate whether they experienced any ‘new symptoms … for four or more weeks (during the survey period) …that are not explained by something else (e.g., pre-existing chronic illness or pregnancy)’. Participants then provided further information including selecting all symptoms they experienced from a list (see Supplementary Material) and providing the onset dates of disruptive symptoms. Participants indicated whether the symptoms had resolved or were ongoing, and were classified as having PCC-compliant symptoms if the duration between onset and survey date (if ongoing) or resolution date (if resolved) was >2 months. Participants whose symptoms were ongoing but with a duration of <2 months were excluded as it was not possible to determine whether their symptoms would resolve. Using date data, the development of symptoms within 3 months of a SARS-CoV-2 or other ARI within each variant period was also evaluated. Where there was no acute infection, attribution to a variant period was based on symptom onset within the variant boundary dates. The outcome of this analysis was the development of long-term symptoms informed by the WHO consensus definition of PCC, and investigation into specific symptom profiles by variant is the subject of a further analysis beyond the scope of this paper.

The survey was sent to the full cohort four times as part of the Virus Watch monthly surveys: in February 2021, May 2021, March 2022, and March 2023. Participants were asked to report on any new-onset long-term symptoms that occurred during the previous year, except in the May 2021 survey where they recalled since February 2020 (when Covid-19 was first reported in the UK [32] as this survey was conducted to account for any non-response to the February 2021 survey. Consequently, responses cover the full period from February 2020 to March 2023. While there may be some overlap in the survey periods, symptoms and their onset dates were matched so that episodes of long-term symptoms could be tracked across multiple surveys.

Covariates

Where indicated (see Statistical Analyses), models were adjusted for the following demographic and clinical covariates collected upon study registration: age (0–11, 12–19, 20–39, 40–64, 65+), sex at birth, deprivation (English Indices of Multiple Deprivation Quintile), binary comorbidity status (presence of any condition on the UK NHS/government list denoting extreme clinical vulnerability or clinical vulnerability [33], ethnicity (White British vs. other), and body mass index (BMI; underweight <18.5 kg/m², healthy weight 18.5–24.9 kg/m², overweight 25–29.9 kg/m², obesity class 1 30–34.9 kg/m², obesity class 2 35–39.9 kg/m², and obesity class 3 > 40 kg/m² [34]). Occupation was classified into the following categories triangulating occupation, exposure risk, and employment status: higher exposure risk occupation, lower exposure risk occupation, retired, not in employment, and unknown/other status. Further details of occupational categories are provided in the Supplementary Material, and details of the occupational coding process are provided in related Virus Watch analyses [Reference Beale, Hoskins, Byrne, Fong, Fragaszy and Geismar35].

COVID-19 vaccination status was accounted for using two variables: number of doses (0, 1, 2, 3, and 4+) and time since vaccination (described below). Maximum number of COVID-19 vaccination doses was defined based on linkage or self-report data up to 7 days prior to infection to allow for a sufficient vaccine response to potentially influence infection, or – if no infection occurred – the maximum number of doses received by the end of the variant period (i.e., the end of follow-up for each exposure period). Time since vaccination was defined as the duration in days between the most recent dose and the date of infection or – if no infection occurred – the end of the variant period, and was included to account for antibody building in the days following vaccination and waning following the peak of protection. Time since vaccination was entered as 0 for unvaccinated participants. To account for the non-monotonic, U-shaped relationship between time since vaccination and associated protection, time since vaccination was entered as a quadratic term in relevant models.

Statistical analysis

We used stratified logistic regressions to investigate how infection status (SARS-CoV-2, other ARI, no infection) during each variant period influenced the odds of developing new-onset long-term symptoms. Variant period was entered as the exposure and models were stratified by infection status to obtain estimates of both the impact of SARS-CoV-2 variant on likelihood of developing PCC (Aim 1) and to facilitate comparison by infection status within each variant dominance period (Aim 2) within comparable models with a consistent adjustment set without requiring an interaction term for vaccination which would impair interpretability of findings related to the primary aims. Comparison with participants who did not experience infection was performed for each variant period to account for background changes in pandemic-related restrictions, contact patterns and other socio-behavioural influences on health.

We developed a directed acyclic graph (DAG) to determine the minimally sufficient adjustment set required to estimate the impact of infection status during each variant period of risk of post-acute sequelae (Supplementary Figure S2); the DAG was considered applicable to all infection status types given that the factors related to exposure to SARS-CoV-2 are relevant to other respiratory infections (vs. no infection). The minimally sufficient adjustment set suggested included age, sex, ethnicity, occupation, deprivation, comorbidities and vaccination status; BMI was also included in the adjustment set in the analyses due to its prominent influence on acute infections and development of long-term symptoms [Reference Xiang, Wu, Jing, Novakovic and Shi36, Reference Dobner and Kaser37]. SARS-CoV-2 vaccination status modifies the risk of acquiring SARS-CoV-2 (dependent on the number of doses and waning due to time since recent dose) and consequently may influence infection status overall by altering the likelihood that an individual be included in the other ARI or no infection groups according to our definitions by influencing SARS-CoV-2 infection risk. Reference categories are as follows in parentheses for each categorical variable: variant period (Omicron BA.2), age (65+), sex (female), ethnicity (White British), occupation (retired), deprivation (IMD 5 – wealthiest quintile), comorbidities (none), BMI (healthy weight), vaccination status (three doses).

While participants could only appear during a single variant period for SARS-CoV-2 infections (see Exposure section), they could appear in multiple variant periods for the Other ARI and no infection groups and consequently cluster robust standard errors were applied for relevant models. Results were expressed as predicted probabilities (average marginal effects (AME) for each variant period based on the logistic models) rather than odds ratios to enable comparison across all variant periods rather than in relation to the reference category and to delineate differences by infection status given the structure of the models. The AME approach involves computing an overall derivative for the estimation sample at each value of the exposure while averaging over observed values of covariates – that is, the average predicted probability of developing long-term symptoms in this sample within each variant period by infection status. This approach is recommended where the effect of the exposure is the primary research question rather than effect modification by covariates [Reference Mize38]. This method was selected rather than setting covariates at specified values, as the aim of this study was to facilitate comparison between variant periods and by infection status within this observational sample, and assessing effect modification or the individual contribution of other demographic and clinical factors was beyond the scope of this study.

Multiple imputation by chained equations was applied to account for missing covariate data (see Table 1 for missingness) using the mice package in R Version 4.0.3 [Reference Van Buuren, Groothuis-Oudshoorn and Vink39], with 5 datasets and 50 iterations per dataset. We conducted a sensitivity analysis using complete cases only to compare with the imputed findings. We also conducted a sensitivity analysis excluding BMI from the adjustment set as it was not required for minimally sufficient adjustment in the final model according to our DAG and had a relatively high proportion of missingness (20%). A further sensitivity analysis was conducted limiting the participants to the sub-cohort who had received serological testing (n = 4,381, 78%), as testing bias and misclassification of asymptomatic SARS-CoV-2 infections may be less likely to affect this group.

Table 1. Features of study participants

^a n (%).