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Analysis of rubella antibody distribution from newborn dried blood spots using finite mixture models

Published online by Cambridge University Press:  25 February 2008

P. HARDELID*
Affiliation:
MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, London, UK
D. WILLIAMS
Affiliation:
MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, London, UK
C. DEZATEUX
Affiliation:
MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, London, UK
P. A. TOOKEY
Affiliation:
MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, London, UK
C. S. PECKHAM
Affiliation:
MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, London, UK
W. D. CUBITT
Affiliation:
Department of Virology, Great Ormond Street Hospital NHS Trust, London, UK
M. CORTINA-BORJA
Affiliation:
MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, London, UK
*
*Author for correspondence: Ms P. Hardelid, MRC Centre of Epidemiology for Child Health, UCL Institute of Child Health, 30 Guilford Street, London WC1N 1EH, UK. (Email: [email protected])
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Summary

Eluted dried blood spot specimens from newborn screening, collected in 2004 in North Thames and anonymously linked to birth registration data, were tested for maternally acquired rubella IgG antibody as a proxy for maternal antibody concentration using an enzyme-linked immunosorbent assay. Finite mixture regression models were fitted to the antibody concentrations from 1964 specimens. The Bayesian Information Criterion (BIC) was used as a model selection criterion to avoid over-fitting the number of mixture model components. This allowed investigation of the independent effect of maternal age and maternal country of birth on rubella antibody concentration without dichotomizing the outcome variable using cut-off values set a priori. Mixture models are a highly useful method of analysis in seroprevalence studies of vaccine-preventable infections in which preset cut-off values may overestimate the size of the seronegative population.

Type
Original Papers
Copyright
Copyright © 2008 Cambridge University Press

INTRODUCTION

Results of antibody assays may be difficult to interpret when used in population-based seroepidemiological studies where quantification of previous exposure to infectious disease, either through natural infection or vaccination, is of interest. This is partly a consequence of the difficulty in applying a meaningful cut-off value to continuous distributions of antibody concentrations in order to define seronegativity [Reference Vyse1]. If a sample falls below a cut-off value set by the assay manufacturer, this does not necessarily indicate non-immunity, as IgG antibody assays for vaccine-preventable diseases are most often employed in screening to indicate a need for immunization. In this context, cut-off values are likely to be set high to avoid false negatives [Reference Ades2]. It follows that using fixed cut-off values for seroepidemiological studies implies an at best artificial, but in some cases completely arbitrary, measure of the population at risk of infection. In addition, since the majority of antibody assays are optimized for measuring antibody concentrations in serum, cut-off values provided by the assay manufacturer may not apply if the assays have been modified for use on other test media [Reference Gay3Reference Talukder5].

An alternative approach is to fit latent-class finite mixture models [Reference McLachlan and Peel6] to continuous distributions of antibody concentrations in order to characterize different exposure categories in the population, e.g. previously infected or vaccinated, and unexposed. The basic assumption in a mixture model is that the study population consists of individuals in different exposure subpopulations. The number of subpopulations is either assumed to be known a priori or, more often, is a quantity of interest to be determined from the data. In either case, mixture models provide a convenient framework to test hypotheses relating to the number of exposure groups in the population and their characteristics. Mixture models have been reported in the literature for analyses of antibody concentrations for various infections [Reference Vyse1, Reference Gay3, Reference Baughman7, Reference Gay8].

In this study, we fit latent-class finite mixture regression models to maternally acquired rubella IgG antibody concentrations obtained from testing residual dried blood spots from newborn screening in North London and surrounding counties in 2004. Since newborn antibody concentration is used as a proxy for maternal antibody concentration [Reference Leineweber9, Reference Goncalves10], we hypothesize that there would be three subpopulations, one seronegative group, a second group with intermediate antibody concentrations that has been vaccinated or infected but mounted a weaker antibody response, and a third group with higher antibody concentrations following infection or vaccination, which is possibly more recent. This model can be expressed as:

(1)
f\lpar y\rpar \equals \pi _{l} f_{l} \lpar y\rpar \plus \pi _{m} f_{m} \lpar y\rpar \plus \pi _{h} f_{h} \lpar y\rpar \comma

where y is antibody concentration, the parameters (πl, πm, πh) are the component weights, and (f lf mf h) are the density functions of the three components.

Maternal age and country of birth have been found to be important predictors of maternal rubella antibody concentration [Reference Tookey, Cortina-Borja and Peckham11]. In order to examine the independent effects of these two variables on maternal antibody concentration, we fit latent-class finite mixture regression models of the form

(2)
f\lpar y\rpar \equals \sum\limits_{k \equals \setnum{1}}^{K} {\pi _{k} \lpar X_{\setnum{1}} \comma \beta _{\setnum{1}k} \rpar \,f_{k} \lpar y\semi \ X_{\setnum{2}} \beta _{\setnum{2}k} \semi \ X_{\setnum{3}} \beta _{\setnum{3}k} \rpar } \comma

where y is the antibody concentration, K is the number of components, X 1, X 2 and X 3 are design matrices for the component weights (π), the location and scale parameters of the kth component respectively. {β1k} is the vector of parameters for the linear predictor in each component weight, and {β2k} and {β3k} are the location and scale parameters. We used the identity, logarithmic and multinomial link functions to fit the regression parameters for location, scale and component weights respectively. We are not aware of any papers reporting the use of this class of mixture regression models to analyse antibody concentrations. We demonstrate their usefulness in quantifying the independent effect of two or more predictors on antibody concentration without dichotomizing this variable.

METHODS

Samples

We measured rubella IgG antibody concentration in dried blood spots, left over from the North Thames newborn screening programme. The newborn screening programme in North Thames covers inner and outer North London, Bedfordshire, Hertfordshire and Essex, an area with an ethnically diverse population. All newborns are offered screening at around 5–8 days of age and coverage is estimated to be close to 100% [Reference Ades12]. Four spots of blood are collected on a Schleicher & Schuell 903® filter paper card (Schleicher & Schuell GmbH, Dassel, Germany) from the baby's heel by a midwife or health visitor who then sends the specimens to the screening laboratory. Blood spot samples are punched from the cards, and tested for biomarkers for inherited or congenital conditions including phenylketonuria and congenital hypothyroidism.

When metabolic screening has been completed, an extra sample is punched from the screening cards and tested for anti-HIV antibody as part of the newborn unlinked anonymous HIV surveillance programme. Anonymized data linkage between screening card data and birth registration records held by the Office for National Statistics was established for this programme. The data linkage and HIV testing algorithm have been described in detail elsewhere [Reference Ades13, Reference Cortina-Borja14].

Laboratory methods

Two extra samples were punched from all blood spot cards sent to the screening laboratory between 1999 and 2006 as part of a study to serotype samples found to be HIV positive [Reference Cortina-Borja15]. As part of the HIV testing protocol, dried blood spot punches are placed in 96-well plates, and eluted in PBS-Tween 20 solution. HIV-positive samples had to be excluded from the analyses, since the remaining eluate is used for HIV confirmatory testing. Following HIV tests, eluates were kept at −20°C for up to 20 months before rubella antibody testing. Plates containing samples received in the screening laboratory in the third quarter of 2004 in North Thames were randomly sampled for rubella IgG testing. A commercial enzyme-linked immunosorbent assay (ELISA; Diesse, Siena, Italy) was used to test for rubella IgG antibody. This ELISA has been found to be valid for use on eluted dried blood spots [Reference Hardelid16]. Dried blood spot eluate samples (50 μl each) were tested for rubella IgG antibody according to the manufacturer's instructions. The ELISA results are quantitative, given as a ratio between the optical density reading of the sample and a plate-specific reference sample provided by the manufacturer. The optical densities can be converted into antibody concentrations in international units per millilitre (IU/ml) using a calibration curve, which is constructed from four plate-specific reference sample values with pre-determined antibody concentrations provided by the manufacturer.

Demographic data

Data on maternal age were available from screening records, and on maternal country of birth through data linkage to birth registration data. Maternal country of birth was coded into a binary variable (‘UK-born’ and ‘born abroad’).

Statistical methods

In order to amplify the values of the optical density ratios between 0 and 1, which are of largest epidemiological and clinical significance, we modelled the distribution of the natural logarithm of the optical density ratio [ln(ODR)]. Low optical density values correspond to seronegative status.

We used the flexmix [Reference Leisch17] and gamlss.mx [Reference Rigby and Stasinopoulos18] packages in the R statistical software version 2.5.1 [19] to fit continuous finite mixture models based on a latent-class regression approach. Both packages employ an expectation-maximization (EM) algorithm that uses maximum likelihood to estimate the model parameters and calculates the probability of belonging to each component for every observation. Hence the size of each component can be estimated as follows: the probability that observation i belongs to class j is given by

(3)
\!\Pr \left[ \,{j\left\vert X_{i\setnum{1}} \comma X_{i\setnum{2}} \comma X_{i\setnum{3}} \semi \ y_{i} \semi \ \beta _{\setnum{1}} \comma \beta _{\setnum{2}} \comma \beta _{\setnum{3}} } \right.} \right] \!\equals\! {{\pi _{j} \lpar {X_{i\setnum{1}} \comma \beta _{\setnum{1}j} } \rpar \ f\lpar {y_{i} } \rpar} \over {\sum\nolimits_{k \equals \setnum{1}}^{K} {\pi _{k} \lpar {X_{i\setnum{1}} \comma \beta _{\setnum{1}k} } \rpar \ f\left( {y_{i} } \right)} }}\!\comma

where j=1, 2, …, K, and i=1, 2, …, n. We used this expression (known as Bayes' rule) to assign each observation to the class with the maximum probability.

We used the diagnostic tools provided by these packages to check the models' goodness-of-fit properties. We based our model selection strategy on the Bayesian Information Criterion (BIC) [Reference Leisch17, Reference Kuha20] defined as

(4)
{\rm BIC} \equals \minus 2\ln L\lpar \hat{\beta }_{\setnum{1}} \comma \hat{\beta }_{\setnum{2}} \comma \hat{\beta }_{\setnum{3}} \rpar \plus p\ln \hskip-1\lpar n\rpar \comma

where L is the value of the likelihood evaluated at the estimates \lpar \hat{\beta }_{\setnum{1}} \comma \hat{\beta }_{\setnum{2}} \comma \hat{\beta }_{\setnum{3}} \rpar, p is the number of model parameters and n is the number of independent observations. The BIC is more conservative against overparameterization than other model selection criteria, which is particularly important when fitting mixture models as the optimal number of components may otherwise be overestimated [Reference Leisch17].

We fitted mixture models to the full distribution of the natural logarithms of the ODRs available, assuming normal and gamma distributions for the components allowing for up to five components and compared the goodness of fit of these models using BIC. In order to fit gamma-distributed components we added a constant to the ln(ODR) values to ensure they were positive. Up to five sets of maximum-likelihood estimates were obtained for each regression model, the optimal model for each set of covariates being that which minimized BIC. Increasing the number of components beyond five resulted in empty components. The finite mixture regression models were then compared using a stepwise procedure to account for one covariate for the mean at a time, then including both variables, and finally including an interaction term. Maternal age was modelled both as a linear and as a quadratic term in the linear predictors defining the components' means. Again, the optimal model was that for which BIC was minimized. The optimal regression model was also refitted with covariates for the component weights and variances, using a stepwise approach, adding more covariates, to assess whether the models' fit improved.

Ethics approval

Ethics approval was obtained from the London Multicentre Research Ethics Committee (MREC).

RESULTS

We analysed ln(ODR)s from 1964 dried blood spot samples out of 1979 samples tested. Eleven samples were excluded from analyses as they were HIV positive, and a further four because parents had opted out of HIV testing or newborn screening. Linkage to birth registration data was achieved for 1943 of 1964 samples (98·9%). Data on maternal age was available for 1265 of these linked samples (65·1%). Mean maternal age was 29·5 years (s.d.=5·9 years). Maternal country of birth was available for 1811 samples (93·2%): 792 (43·7%) mothers were born abroad. The distribution of ln(ODR) by maternal age group (<25, 25–34 and ⩾35 years) and country of birth are shown in Figure 1(ab).

Fig. 1. Distribution of the natural logarithm of the optical density ratio [ln(ODR)]: (a) by maternal age group (n=1265); (b) by maternal country of birth (n=1811).

Table 1 shows the model selection process for the finite mixture models using the full population of 1964 samples, varying the number of mixture model components, assuming normal or gamma distributions of the components. The former appeared to provide a better fit, and therefore all subsequent models were based on this assumption. The model with three normally distributed components had the lowest BIC; the three normal density functions correspond to the three hypothesized groups of exposure to rubella infection (Table 2). Note that the component weights are not equal to the proportions of samples allocated to each component since the former are the estimates of the parameters πl, πm and πh and the latter were calculated using equation (3).

Table 1. Model selection procedure for univariable finite mixture models (n=1964)

d.f., Degrees of freedom; BIC, Bayesian Information Criterion.

Table 2. Summary of the three components in the univariable model with lowest Bayesian Information Criterion (means and confidence intervals have been anti-logged)

ODR, Optical density ratio, s.d., standard deviation; CI, confidence interval.

Figure 2 shows the densities of each component of this model, as well as the density of the total sample of ln(ODR).

Fig. 2. The density functions of the three components of the finite mixture model with lowest Bayesian Information Criterion and the density function of the total distribution of the natural logarithm of the optical density ratio [ln(ODR)] (n=1964).

To account for the variation in antibody concentration by maternal age and country of birth, we fitted mixture regression models adjusting for these covariates. In order to compare models with different covariates using the BIC, all samples for which either maternal country of birth or maternal age was missing had to be excluded, leaving 1236 samples for analysis. A summary of these regression models can be found in Table 3.

Table 3. Model selection strategy for mixture regression models (n=1236)

d.f., Degrees of freedom; BIC, Bayesian Information Criterion.

The BIC was minimized for the model where only maternal country of birth is included as a covariate (model 3). This model was therefore refitted with covariates for the component weights (π) and variance parameters using the same combinations of covariates as described in Table 3.

A model in which maternal age was included as a covariate for the component weights (with no covariates for the variances) improved very marginally on the optimal model described in Table 3 and resulting in a BIC of 2503·6. The parameter estimates for the linear predictors of this model are shown in Table 4a; note that the functions for the component weights are given on the multinomial scale, considering the low component as baseline. Table 4b gives the mean and confidence interval (CI) for the components by maternal country of birth.

Table 4a. Linear predictors for the optimal model

Table 4b. Summary of the optimal mixture regression model with maternal age as a covariate for the component weights (π) and maternal country of birth as a covariate for the mean of the components (means and confidence intervals have been anti-logged)

ODR, Optical density ratio; CI, confidence interval.

* The number of samples in each component was estimated using the posterior probabilities derived using equation (3).

The mean ODR for the low and medium mixture model components is significantly lower for women born abroad than for UK-born women. However, for UK-born women, the mean of the medium component is not significantly different to that of the low component. Figure 3 shows how the component weights change as a function of maternal age. These curves were obtained by applying the inverse multinomial function to the linear predictors in Table 4a. Adding a quadratic effect for maternal age to these probability functions did not improve the goodness of fit.

Fig. 3. Component weights (π) by maternal age for the optimal model described in Tables 4 a and b.

As maternal age increases, women are less likely to be assigned to the low component. The probability of being assigned to the medium component increases with maternal age, however, the proportion in the higher component changes little across maternal ages. For a mother of the mean age in our sample (29·5 years), the component weights for the low, medium and high components are therefore 5·7%, 54·1% and 40·2% respectively.

DISCUSSION

Left-over dried blood spots from newborn screening provide a large, relatively inexpensive, and near-universal sampling frame within which rubella antibody concentrations among newly delivered women can be investigated. However, because this implies using newborn antibody concentration as a proxy for maternal antibody concentration, using cut-off values to define the seronegative population would not be appropriate for our data. We therefore used finite mixture models to analyse the natural logarithms of the ODRs, as this avoids dichotomizing the outcome variable of interest.

Several authors [Reference Vyse1, Reference Gay3] have commented on the usefulness of finite mixture models for analysing results of seroprevalence studies in which the specificity of the antibody assay used is low. This is supported by our findings; using this approach and assuming that the samples allocated to the component with the lowest mean antibody concentration are seronegative (Table 2), 3·6% of samples would be considered antibody negative (95% CI 2·8–4·4). This is similar to the proportion of women who were described as susceptible through antenatal screening in London in 2004 [Reference Giraudon21]. By applying the cut-off recommended by the assay manufacturers (of samples with an antibody level <7 IU/ml classed as seronegative), the proportion of samples that would be considered seronegative is 15·3% (95% CI 13·8–17·0), which is a gross overestimate. This emphasizes the need for caution in applying cut-off values determined a priori, which are intended for use in a clinical setting, without consideration for the particular context in which they are applied, or of the specimens used in the serosurvey.

As Figure 2 shows, there is some overlap among the components of the mixture model. This implies that some samples (e.g. with log optical densities between −1 and 0), which may have been assigned to the medium antibody component also have a non-negligible probability of being assigned to the low antibody component. This raises some questions about the validity of determining a cut-off value based on this particular mixture model.

Since data on maternal country of birth were available from data linkage between the newborn screening records and birth registration data, and maternal age could be obtained from screening datasets, finite mixture regression models could be fitted, allowing the means, component weights and variances in the model to vary by risk factors. In previous studies where finite mixture models have been used, only age group has been of interest as a predictor of antibody level [Reference Vyse1, Reference Gay3, Reference Gay8], and mixture models are therefore often stratified in order to determine the proportion of seronegative samples in each age group. This is important in order to establish whether further vaccination is required due to higher susceptibility in some cohorts. However, maternal country of birth or ethnic group has been reported to be a highly significant predictor of rubella susceptibility among pregnant women in the United Kingdom [Reference Tookey, Cortina-Borja and Peckham11, Reference Miller22]. Our method allows hypotheses about the independent, as well as the combined effects, of age and country of birth on antibody concentration to be tested.

In our optimal model, the means of the low and medium components for women born abroad were significantly lower than those for women born in the United Kingdom, yet the component weights were not found to vary by country of birth. One possible reason for this is that women born in the United Kingdom with low antibody concentrations may have been exposed to the virus through vaccination several years previously and therefore their antibody concentrations may have waned without ‘boosting’ through contact with wild virus. This is in contrast to women born abroad with low antibody levels who may not have had previous virus contact. For UK-born women, the difference in means between the low and the medium component was not statistically significant. A larger sample size will allow the component means to be more precisely estimated, as well as the inclusion of a more detailed maternal country-of-birth variable to identify specific groups at high risk of infection during pregnancy.

We also found that the weight for the low component decreased as maternal age increased, but increased with maternal age for the medium component, implying that younger pregnant women are more likely to be seronegative, as defined by the mixture models. Vyse et al. [Reference Vyse1] also found a similar age pattern of rubella seronegativity among women in England and Wales. This could be a consequence of the antenatal screening programme, where women who screened negative in a previous pregnancy were vaccinated post partum.

With the possibility of adjusting for several covariates, it is important that the model selection process avoids models which overfit the number of components as well as the number of covariates. The flexmix and gamlss.mx R-packages allow for the calculation of BIC as a model selection statistic. In comparison to using log-likelihood only, the BIC penalizes both for sample size and the number of parameters, and is therefore more conservative in terms of the optimal number of components and variables included (Table 3). The use of BIC for model selection in finite mixture regression models depends, as all likelihood-based procedures, on all competing models being fitted to the same dataset. Because maternal age was missing for a large proportion of samples, this resulted in the sample sizes for the regression models including this covariate being reduced by about 40%.

Several previous papers [Reference Vyse1, Reference Gay3, Reference Gay8] in which mixture models were applied to results of seroprevalence studies have assumed normal distributions for the mixture model components. We tested the assumption that gamma-distributed mixture model components provided a better fit, however, this was found not to be the case.

In this paper we have distinguished between the estimates of the component weights (π1, π2, …, πK) and the estimated proportion of observations in each component, which is calculated based on the posterior probabilities given in equation (3). This is the only feasible approach for finite mixture regression models fitted with covariates for the component weights. Indeed, this procedure should be used even in finite mixture regression models without covariates for the component weights since the posterior probabilities allow the assessment of how well defined the components are. The posterior probabilities also allow the analysis of the characteristics of the individuals whose samples have been assigned to a particular component. Using our approach, it can be shown that 60·4% of women whose samples were assigned to the low component described in Table 4b were born abroad. This would not have been possible if component weights had been used to estimate the size of the components.

The use of residual dried blood spots from newborn screening anonymously linked to birth registration data provides a near-universal sampling frame from a large and ethnically diverse area such as North Thames. This allows differences in maternal rubella antibody concentrations by maternal age and country of birth to be investigated. We have demonstrated that latent-class finite mixture regression models are a powerful statistical method for analysing antibody concentrations from serosurveys in which assay cut-off values are not applicable. Fitting these models allows inclusion of linear predictors for antibody concentration and the identification of groups of pregnant women who may require vaccination. Newborn dried blood spots can therefore be used to obtain more detailed estimates of the proportion of women who are seronegative in different age and country-of-birth categories.

ACKNOWLEDGEMENTS

We are grateful to Bettina Grün, Fritz Leisch and Mikis Stasinopoulos for their suggestions on computational issues, to Louise Logan for her help with data linkage, and to an anonymous referee for helpful comments. This research was funded by the Medical Research Council, grant number G0300654. Research at the UCL Institute of Child Health and Great Ormond Street Hospital for Children NHS Trust benefits from R&D funding received from the NHS Executive.

DECLARATION OF INTEREST

None.

References

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Figure 0

Fig. 1. Distribution of the natural logarithm of the optical density ratio [ln(ODR)]: (a) by maternal age group (n=1265); (b) by maternal country of birth (n=1811).

Figure 1

Table 1. Model selection procedure for univariable finite mixture models (n=1964)

Figure 2

Table 2. Summary of the three components in the univariable model with lowest Bayesian Information Criterion (means and confidence intervals have been anti-logged)

Figure 3

Fig. 2. The density functions of the three components of the finite mixture model with lowest Bayesian Information Criterion and the density function of the total distribution of the natural logarithm of the optical density ratio [ln(ODR)] (n=1964).

Figure 4

Table 3. Model selection strategy for mixture regression models (n=1236)

Figure 5

Table 4a. Linear predictors for the optimal model

Figure 6

Table 4b. Summary of the optimal mixture regression model with maternal age as a covariate for the component weights (π) and maternal country of birth as a covariate for the mean of the components (means and confidence intervals have been anti-logged)

Figure 7

Fig. 3. Component weights (π) by maternal age for the optimal model described in Tables 4 a and 4 b.