1) Understanding the data source.

Data were extracted from Hospital Episode Statistics (HES). HES is an administrative database holding detailed information for all admissions to NHS hospitals in England, and has been collected since 1989, primarily for financial purposes. HES data are made available to researchers with appropriate permissions, in a pseudonymised form (i.e. without personal identifiers) from the HSCIC. Data are divided into financial years, and structured as ‘episodes’ of care, within which a patient is under the care of one consultant. Each admission may comprise multiple episodes; episodes relating to the same individual are assigned the same pseudonymous ID (HESID) by the data provider, allowing researchers to track patient admissions over time without accessing any personal identifiers. HESID is assigned using a deterministic rule-based algorithm based on NHS number, local patient identifier, sex, date of birth and postcode.[19]

HES records contain clinical diagnoses (coded using the International Statistical Classification of Diseases and Related Health Problems 10th Revision: ICD-10[20]), procedures (coded using the Office of Population Censuses and Surveys Classification of Surgical Operations and Procedures 4^th revision: OPCS), and Healthcare Resource Groups (HRGs: http://www.hscic.gov.uk/hrg). Standard HES extracts also include sex, month and year of birth and ethnic category (UK census 18 categories). Geographical information includes organisational code (NHS Trust or Primary Care Trust), registered GP practice code, residential postcode district (first 3–4 postcode characters; each postcode district contains an average 9500 UK households) and Index of Multiple Deprivation (IMD, derived from postcode).[21–23]

In addition to the main HES record, delivery episodes for mothers and birth episodes for babies include additional fields called the ‘baby’ (or ‘maternity’) tail.[21] The baby tail contains information on delivery, including gestational age, birth weight and mode of delivery. For multiple births, each delivery record can hold up to 9 baby tails (up to 6 prior to 2002). The baby tail should contain the same information on both maternal and baby records, but is sometimes incomplete.[15] There is no routine linkage of maternal and baby records within HES: the maternal NHS number is not available on the baby record or vice versa.

2) Identifying delivery and birth records.

All records relating to birth and delivery episodes for babies and mothers between April 2001 and March 2013 were extracted from HES. Birth episodes can be identified in a number of ways within HES.[15, 18] For this study, maternal (delivery) records were identified by the presence of ICD-10 codes Z37-Z38 (outcome of delivery, liveborn infant), OPCS codes R14-R27 (delivery procedures), or two or more valid baby tail fields (excluding numpreg, numbaby, neocare and well_baby). Baby (birth) records were identified by the presence of ICD-10 codes Z37-Z38, HRG codes N01-N05 (neonates) or HES fields relating to episode type, method of admission, age at start of episode and level of neonatal care. Ectopic pregnancies, terminations and duplicate episodes were excluded. Full descriptions of the code lists are provided in Tables A and B in S1 Appendix.

Maternal records with the same HESID but with episodes <169 days (24 weeks) apart were treated as duplicates (except for multiple births). Baby records with the same HESID, episode start date, start age, postcode district, birth order and birth weight were treated as duplicates. Information on duplicate records was combined and a single record retained. Where multiple births were recorded on the same maternal record, separate delivery records were created for each birth to facilitate linkage with distinct birth records.

The algorithm for assigning HESIDs to multiple episodes of care for the same individual can introduce errors.[24] Where the same HESID was assigned to multiple individuals, records were dropped, as it was not possible to identify the correct record. Where the same individual was assigned multiple HESIDs (i.e. multiple HESIDs for the same episode start date, age, hospital, GP practice, ethnicity, month-year of birth and baby tail fields), records were treated as duplicates and a log was kept of the relevant HESIDs (to facilitate linkage with subsequent episodes of care).

Birth outcomes were identified from clinical information in either baby or maternal records. Multiple births were identified by ICD-10 codes (Z372-Z377 or Z383-Z388), or HES fields ‘birordr’ (birth order) and ‘numbaby’ (number of babies). Preterm births were identified using ‘gestat’ (gestational age) or ICD-10 codes P072, O60 or P590. Still births were identified using three categories of codes: ‘dismeth’ (discharge method), ‘birstat’ (birth status) and ICD-10 diagnosis (see Table C in S1 Appendix for the full code list description).

3) Data preparation.

Since postcode is not always completed for birth episodes in HES, postcode was imputed using subsequent episode records up to one year after the birth episode. Where ‘sexbaby’ was not completed for baby records, ‘sex’ as recorded on the main HES record was used.

We hypothesised that any coding errors could occur simultaneously in corresponding maternal and baby records (i.e. if data were input to both records through the same system), and so only minimum data cleaning was applied prior to linkage.[25] Generic values for “not known” or “not applicable” were set to missing. All string variables were trimmed to remove blank characters and instances of “&”, “-”etc were removed (see Table A in S2 Appendix).

4) Data linkage.

Data linkage methods. There are two main approaches for linking data: deterministic and probabilistic. Deterministic linkage (or rule-based matching) typically requires exact or approximate agreement on a set of common identifiers (e.g. sex, postcode and date of birth). Exact deterministic matching generally achieves few false-matches (where records belonging to different individuals are linked), as it is unlikely that two individuals share the same set of identifiers. However, requiring exact agreement on identifiers can result in low match rates, as any errors or missing values can prevent a match (resulting in missed-matches, where records belonging to the same individual remain unlinked). Deterministic methods can also incorporate approximate matching, e.g. on month and year of birth, phonetic codes or string comparators for names, or dates within a particular timeframe.

Probabilistic linkage is based on deriving a match weight that represents the likelihood of records belonging to the same individual, given the agreement or disagreement on a set of common identifiers.[26] This approach accounts for the discriminative value of each identifier, i.e. agreement on postcode district would contribute more evidence of a match than agreement on sex. Calculation of the match weight depends on the estimation of two conditional probabilities:

• M-probability: the probability that an identifier agrees given records belong to the same individual
• U-probability: the probability that an identifier agrees given records belong to different individuals

The u-probability can be approximated by the probability of chance agreement. For example, the probability of chance agreement on sex is ½. The probability of chance agreement on month of birth is 1/12, and so on. M-probabilities represent the error rate in a particular identifier, and are typically estimated during the linkage process, and updated as more links are made. For example, if sex was miscoded in 5% of record pairs, the m-probability would be 0.95. Frequency-based weights can also be derived, which allows agreement on more rare values to contribute a higher weight.

The overall match weight is derived by calculating the ratio log₂(m/u) for each identifier, and summing across all identifiers. Record pairs with agreement on multiple identifiers will have large positive match weights; record pairs with disagreement on most identifiers will have negative match weights.

Probabilistic linkage requires cut-off weights to be chosen for classifying record pairs as links or non-links, consequently determining the rates of missed-matches and false-matches. Typically, two thresholds are chosen, and record pairs with weights falling between the thresholds are subjected to further manual review. However, manual review processes can be both subjective and prohibitively time-consuming for large datasets, and often depend on having access to detailed identifying information. An alternative method is to set an optimal error rate (e.g. maximum allowed false-match rate) and to evaluate error rates for a range of threshold values. Estimation of linkage error rates at each potential threshold requires that the true match status is known, and is typically performed using a subset of gold-standard data (e.g. manual review of a sample of records) or by generating synthetic data with similar characteristics to the original data.[27]

Data linkage methods in this study. In this study, we firstly used exact deterministic linkage to bring together maternal and baby records, and supplemented this approach with probabilistic linkage of remaining unlinked records (Table 1). To reduce the number of comparison pairs, an initial blocking strategy was employed: mother and baby records were only considered as possible matches if they had been admitted to the same hospital and record pairs with implausible dates were not considered (baby discharged prior to the mother’s admission or mother discharged prior to the baby’s admission). This blocking strategy was subsequently relaxed to capture mothers and babies in different hospitals or where episode dates differed.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Table 1. Completeness of potential linkage variables in maternal and baby HES records for 2012/13.

https://doi.org/10.1371/journal.pone.0164667.t001

Deterministic links were identified as records agreeing exactly on GP practice, maternal age, birth weight, gestation, birth order and sex. Our approach allowed for missing values, as long as at least three of the agreeing variables were complete, and there were no disagreeing values on any variable.

For our probabilistic approach, we used frequency-based match weights since the probability of agreement on a particular variable may vary according to the value of that variable. Frequency weights were derived for each value of gestational age, delivery place (intended), status of person conducting delivery, postcode district (first letter) and ethnic category). For example, this allowed for a higher chance of agreement on a gestational age of 40 weeks (a common value) than 26 weeks (a rare value). Episode start and end dates for mothers and babies could also genuinely be different, e.g. if the mother was admitted the day before delivery. Therefore for dates, match weights were calculated depending on the difference in the number of days (0, 1, 2, 3, 4, 5, 6, 7, 8–14 and 14+ days). Records with dates a small number of days apart would therefore have higher match weights than those that were more than a week apart.

In our study, initial estimates for the m-probabilities were obtained using the deterministically-linked records. U-probabilities were obtained from pairwise comparisons of a random sample of 5000 unlinked records (i.e. 25,000,000 comparisons). Estimates were then iteratively updated using the probabilistically-linked records according to the following steps:

1. Initial match weights were assigned to all record pairs
2. Record pairs were manually reviewed and non-links were removed
3. M-probabilities were re-estimated based on the remaining record pairs
4. New match weights were assigned to all record pairs
5. The process was repeated until match weights stabilised (three iterations in this study)

There is no gold-standard for linkage of maternal and baby records in HES, and even if it were possible to access personal identifiers, maternal and baby HES records do not share a unique identifier. Therefore, linkage quality was evaluated by testing the algorithm and estimating the match rate and false-match rate on synthetic data. Full details of the synthetic data approach are provided in S3 Appendix; in brief, 100 synthetic datasets with similar identifier error rates and missing values to HES were created, where the true match-status was known; after applying the linkage algorithm to each synthetic dataset, false-match rates were estimated.

Completeness of HES fields is known to have improved over time.[15] Therefore, we compared linkage rates for 2001/02 and 2012/13. In order to evaluate the relative contribution to linkage success of more sensitive linkage variables (postcode district and GP practice), we repeated the linkage process excluding these variables.

5) Internal and external validity.

We firstly compared values of gestational age and birth weight with published reference values and set to missing values falling more than 3 standard deviations from the average.[28] We then assessed internal validity of maternal and baby records by checking consistency of three rare but important birth outcomes (still births, multiple births and preterm births). Linked maternal-baby records that were discordant on these outcomes were resolved using corroborating information in HES (additional ICD-10 diagnosis codes, the presence of multiple maternity tails, or subsequent admission records).

The representativeness of the linked cohort was evaluated by comparing distributions of key birth characteristics and outcomes with national published data (compiled on birth registrations) from the Office for National Statistics (ONS). Differences were identified using chi² tests for categorical data, t-tests for normal data and the Mann-Whitney U test for skewed data.

Preterm birth.

Gestational age was available for 546,083/660,401 (83%) linked baby records and 567,699/660,401 (86%) linked maternal records for 2012/13. Completeness of gestational age increased to 92% when using information from either record. Gestational age was discordant on 4% of linked baby-maternal records, and the majority of these (71%) differed by 1 or 2 weeks only. For discordant records, the value in the maternal record seemed to be more accurate (based on birth weight for gestational age). Only 4 records had an ICD-10 code for preterm birth but a gestational age >37 weeks.

Multiple births.

Multiple birth status was discordant in 1860/660,401 (0.3%) record pairs, suggesting missing or inaccurate records. For 617 pairs, there was evidence of a multiple birth in the maternal record but not in the baby record. For 1243 pairs, there was evidence of multiple birth in the baby record, but only one maternal record.

Still births.

Still birth status was discordant in 1232/660,401 (0.2%) record pairs. For 1165 pairs, still birth was recorded in the maternal record but not the baby record. For 67 pairs, stillbirth was recorded in the baby record but not the maternal record. Discordant records were resolved by checking the baby’s length of stay: if length of stay was >1 day, still births were reclassified as live births. The majority of these errors were related to multiple births: maternal records with ICD10 code Z373 (Twins, one liveborn and one stillborn) or birth status in the maternity record baby tail.