Association of physical and sexual assault with mortality in two British birth cohorts

Cohort details

Data for this study were from the 1958 National Child Development study (NCDS, referred to as the 1958 birth cohort hereafter), a birth cohort collecting data on all live births taking place in a single week in 1958 in England, Wales and Scotland34; and the 1970 British Cohort Study (BCS, the 1970 birth cohort hereafter), a birth cohort collecting data on all live births taking place in England, Scotland, Wales and Northern Ireland in a single week in 1970.35 Measurements on all variables in this study, including ages of measurement, are summarised in figure 1. A flow diagram showing the study sample was arrived at is displayed in figure 2.

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Measurements

Measurement of mediators

To assess psychological distress as a potential mediator of the association between assault and mortality, we included similar data on psychological distress based on measurements collected on the Malaise Inventory at age 42 in 2000 (1958 birth cohort) and 34 in 2004 (1970 birth cohort). To measure alcohol, units of alcohol consumed per week were taken at age 42 in the 1958 birth cohort and age 34 in the 1970 birth cohort, using conventional formulae for converting self-reported weekly consumed quantities of different beverages (beer, wine, shandy, sherry, spirits and alcopops (1970 birth cohort only)) to units of alcohol consumption.36 To measure cigarette smoking, we used measurements of current numbers of cigarettes smoked at age 42 in the 1958 birth cohort and age 34 in the 1970 birth cohort. Measurement of covariates is described in the methodological supplement.

Analysis

Data were analysed by using Stata V.17.37 Individuals with missing data on assault were excluded. Counts and proportions of cohort members experiencing any assault, and the number of total assaults, were described by covariates for each birth cohort separately. To account for confounding, adjustment variables were selected for inclusion based on a review of the literature for each characteristic’s influence on both assault and mortality. A directed acyclic graph displaying pathways underlying the analysis is shown in online supplemental figure 1. Data on continuous variables (alcohol use, cognitive (verbal) ability) from both birth cohorts were z-standardised to have a mean of 0 and an SD of 1, and all were included as linear terms after assessment of difference in goodness of fit versus quadratic terms and indicator terms for each quintile (measured by the Akaike information criteria and the Bayes information criteria, see online supplemental table ST1). We used information on how many years ago each assault occurred to derive a variable for age of assault, describing this in both cohorts (online supplemental table ST2).

To test any association between assault and mortality, Cox regression models were estimated including 1 January 2000 as the start of the at-risk period, defining death as the time-to-event outcome and censoring defined by being unavailable for follow-up at any wave of data collection, or the conclusion of the time-at-risk. Graphical inspection of log/log plots (see online supplemental figure 2) and of Schoenfeld residuals were used to check departure from the assumption of proportionality of hazards. Kaplan-Meier graphs for each cohort stratified by any assault are displayed in online supplemental figure 3 (1958 cohort) and 4 (1970 cohort). Models were estimated for any assault (ie, either physical or sexual assault), physical assault, sexual assault, a count variable for the number of assaults, and highest level of medical treatment for any assault (classified into no assault, medical treatment but not overnight and overnight treatment). All analyses were carried out on data combining the two birth cohorts, and on each birth cohort separately—we also tested for interaction by cohort year. To report the impact of adjustments for different confounders, we estimated the crude association (model I), models only adjusting for gender, adverse childhood experiences and birth year only (model II), then further adjusting for socioeconomic variables (marital status, class, educational attainment, model III) and then further adjusting for model III variables and prior psychological distress, verbal ability and alcohol use (model IV, the final model). For adjusted analyses combining both cohorts, we adjusted for adverse childhood experiences using the restricted definition of adverse childhood experiences (excluding neglect) to ensure uniformity of definitions between the cohorts. For analyses of 1958 birth cohort data, we estimated models with both definitions of adverse childhood experiences (including and excluding neglect). To assess the impact of differing reference periods for assault measurement on our results, combined cohorts analyses were estimated excluding either the early or the late reference period for 1958 birth cohort data (presented in online supplemental table ST3). Based on the final model for the combined cohorts, we tested for differences between men and women, by the presence of prior psychological distress, and by cohort year, using multiplicative interaction terms, setting p≤0.05 as the criterion for determining significant interactions.

To address the impact of missing data, we also estimated the same models based on 10 multiply imputed datasets, using the mi command in Stata, which deploys multiple imputation with chained equations. Imputation commands for each missing variable were specified based on their form in complete case models—imputation models contained: sex, marital status and prior psychological distress, imputed by logistic regression; adverse childhood experiences, social class and educational attainment, imputed by ordinal logistic regression and cognitive (verbal) ability and alcohol use imputed by linear regression. Directions of associations remained after accounting for missing data in imputations (based on the missing at-random assumption).

In addition to Cox models, we used the gformula package to explore mediation.38 According to a counterfactual framework, G formula analyses contrast-specific exposure (or treatment) scenarios—in this case, comparing a scenario where the entire population is assigned to no exposure (eg, no assault), with the scenario where the population is assigned to exposure (assault). To examine mediation of the association between assault and mortality by the candidate mediators (psychological distress, alcohol use and cigarette smoking), we estimated total controlled effects, direct effects (DE) and natural indirect effects (NIE) for any assault. The DE represented the effect of assault on mortality that was independent of each respective mediator. The NIE represented the proportion of mortality that could be explained by its association with changes in each respective mediator over time. To quantify the magnitude of mediation, we estimated the proportion of the association mediated (NIE/[DE+NIE]). G formula models further adjusted for general health status as a postbaseline mediator-outcome confounder (as shown in online supplemental figure 1). For missing data, the gformula package implements single stochastic imputation using chained equations. We included identical specifications of each variable in G formula models as in Cox models described above.

Patient and public involvement

Patients or the public were not involved in the design, or conduct, or reporting, or dissemination plans of our research.

Description

Association of assault and mortality

Figure 3 graphically displays multiple imputation-based estimates for the association of assault with mortality; a table of partially adjusted estimates is reported in online supplemental table ST6. Based on multiply imputed data, the fully adjusted estimate for assault on mortality was 1.72 (95% CI 1.22 to 2.42) in the combined cohorts, 1.53 (95% CI 0.97 to 2.40) in the 1958 birth cohort and 2.05 (95% CI 1.20 to 1.50) in the 1970 birth cohort (see figure 3). Results for physical assault specifically were similar to any assault in direction and magnitude. The fully adjusted estimate for the association of sexual assault with mortality was 3.17 (95% CI 1.17 to 8.60) in the combined cohorts, 1.36 (95% CI 0.19 to 9.81) in the 1958 birth cohort and 6.02 (95% CI 1.84 to 19.69) in the 1970 birth cohort. The fully adjusted mortality HR for one additional assault was 1.46 (95% CI 1.23 to 1.73) in the combined cohorts, 1.34 (95% CI 0.99 to 1.82) in the 1958 birth cohort and 1.53 (95% CI 1.25 to 1.87) in the 1970 birth cohort. Greater need for medical treatment for assault was associated with a fully adjusted mortality HR of 1.56 (95% CI 1.19 to 2.05) in the combined cohorts, 1.43 (95% CI 1.00 to 2.05) in the 1958 birth cohort and 1.79 (95% CI 1.18 to 2.74) in the 1970 birth cohort. Estimates from complete-case analysis are reported in online supplemental table ST7.

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Figure 3

Diagram displaying fully adjusted model estimates (HRs) from multiple imputation for the association of any assault, physical assault, sexual assault, number of assaults and need for treatment for assault, with mortality. Estimates are adjusted for sex, cohort year, ACEs, socioeconomic variables (class, educational attainment and marital status), and alcohol and cognitive/psychiatric covariates (alcohol use, cognitive (verbal) ability and prior depressive symptoms). ^aBased on data from 19 725 individuals. ^b1958rACE refers to estimates for the 1958 birth cohort employing a restricted definition of ACEs (leaving out neglect) to allow comparison with 1970 birth cohort estimates. Based on data from 10 019 individuals. ^c1958fACE refers to estimates for the 1958 birth cohort employing the full definition of ACEs (including neglect). Based on data from 10 019 individuals. ^d1970 birth cohort estimates were based on data from 9706 individuals. ACEs, adverse childhood experiences.

Summary of findings

We report the first prospective examination of association of exposure to physical or sexual assault in adulthood, with all-cause mortality in data from two British birth cohorts. We observed strong mortality associations for exposure to any assault, physical assault specifically, an increasing number of assaults and an increasing severity of assault (as indicated by the level of medical treatment received), on analysis of the combined cohorts. Statistical evidence for association of sexual assault, specifically, with mortality was incomplete due to small numbers of individuals reporting sexual assault. We did not find evidence for mediation of this association by intermediate psychological distress, alcohol use or cigarette smoking.

Limitations and strengths

We made use of detailed self-report information on exposure to physical and sexual assault. Final estimates for our main comparison, the association of assault with mortality, were statistically significant and based on large nationally representative British birth cohorts. We demonstrated trends in associations with assault number, and with assault severity (as indexed by degree of medical treatment), strengthening inferences of association between assault exposure and mortality. To our knowledge, we present the first epidemiological description of assault data in these birth cohort studies—with age distributions for assault exposure being consistent with existing evidence suggesting greater occurrence of assault exposure in younger age groups.6

Data on the location of assaults, and relationship of individuals exposed to assault to the perpetrator, were not collected. Informative censoring, for example, through greater censoring of individuals at higher risk of the both the exposure and the outcome could have resulted in bias in our estimates, probably in the null direction. Data on individuals who experienced assault and then died before the start of observation time were not used, which may have introduced bias towards the null through omission of individuals with shorter failure times. Use of self-report data on assault could have introduced reporting bias, if, for example, the probability of reporting assault was related to mortality risk, however, main drivers of mortality are unlikely to have affected recall. Other methods of measuring assault, such as direct use of linked hospital records, could have generated more temporally precise data. Our study examined individuals who sought medical attention for assault rather than the larger population exposed to any assault. Although we adjusted for theoretically guided confounders, residual confounding by unknown common causes of assault and mortality remains possible, including for indirect effects. We excluded non-white individuals from our analysis because of very small numbers of exposed individuals from minority ethnic groups, limiting the generalisability of our results. The use of two birth cohorts, collected 12 years apart, allowed testing for cohort differences in associations, but also involved the pooling of assaults data collected during different life periods (age 25–42 in 1958 birth cohort and age 21–30 in the 1970 birth cohort), limiting our ability to assess the impact of age of exposure on our results. Although crude estimates for the association of sexual assault with mortality suggested a statistically significant association, fully adjusted estimates were statistically imprecise, indicating that confounding cannot be excluded as an explanation for this association based on current evidence. We estimated a number of statistical comparisons, which likely increased the likelihood of type I error. However, these were prespecified and our estimates of association were consistent in terms of direction across the different comparisons.

Finally, differences in estimates from multiply imputed data from estimates drawn from complete-case analysis suggests bias introduced by missing data when considering analyses of complete cases.

Explanations

Our previous work indicated association of physical assault with mortality in men living in Russia11 but was unable to examine intermediate explanations. Kelly-Irving et al39 report the influence of adverse childhood experiences on mortality but did not examine the role of exposure to assault in adulthood. Participants in a longitudinal study of Danish adults who reported the highest frequency of relationship conflict (including with partners, family members, coworkers and neighbours) experienced significantly greater mortality. This analysis did not examine violence specifically, limiting its implications for violence specifically.40 Our findings make a further contribution to evidence on violence exposure and population health.

The evidence we found for a relationship between count of assaults and mortality implies a role for accumulated experience of interpersonal violence in adulthood and mortality through the ‘wear and tear’ of body systems, as proposed in the allostatic load hypothesis.41 Under the allostatic load hypothesis, the accumulation of stressful experiences, including violence, could result in chronic activation of physiological stress responses, including the hypothalamo–pituitary–adrenal axis, driving inflammatory and degenerative processes and increasing mortality, for example, through cardiovascular disease.41