Abstract
Patient registry data are commonly collected as annual snapshots that need to be amalgamated to understand the longitudinal progress of each patient. However, patient identifiers can either change or may not be available for legal reasons when longitudinal data are collated from patients living in different countries. Here, we apply astronomical statistical matching techniques to link individual patient records that can be used where identifiers are absent or to validate uncertain identifiers. We adopt a Bayesian model framework used for probabilistically linking records in astronomy. We adapt this and validate it across blinded, annually collected data. This is a high-quality (Danish) sub-set of data held in the European Cystic Fibrosis Society Patient Registry (ECFSPR). Our initial experiments achieved a precision of 0.990 at a recall value of 0.987. However, detailed investigation of the discrepancies uncovered typing errors in 27 of the identifiers in the original Danish sub-set. After fixing these errors to create a new gold standard our algorithm correctly linked individual records across years achieving a precision of 0.997 at a recall value of 0.987 without recourse to identifiers. Our Bayesian framework provides the probability of whether a pair of records belong to the same patient. Unlike other record linkage approaches, our algorithm can also use physical models, such as body mass index curves, as prior information for record linkage. We have shown our framework can create longitudinal samples where none existed and validate pre-existing patient identifiers. We have demonstrated that in this specific case this automated approach is better than the existing identifiers.
Highlights
Registries are used to describe the clinical status of patients and foster care improvement [1] and are invaluable tools in the analysis of rare diseases because of the limited number of patients affected in a given geographical zone, as reviewed recently [2]
Creating longitudinal datasets in a cystic fibrosis registry using a novel approach from astronomy to the point of data entry as possible
We show that new longitudinal data sets can be constructed at a patient level in the absence of unique identifiers and that the validity of any existing and supposedly ‘gold standard’ identifiers can be verified
Summary
Registries are used to describe the clinical status of patients and foster care improvement [1] and are invaluable tools in the analysis of rare diseases because of the limited number of patients affected in a given geographical zone, as reviewed recently [2]. Catalogues of galaxy position and brightness are made from each telescope and cross matched such that for each galaxy, we know its position on the sky and how its brightness changes at different wavelengths. This allows us to fit models and constrain properties such as the SFR. Because of the longer wavelength, and the limit to the size of telescope mirror for space-borne facilities, the resolution of these observations is low relative to those at lower wavelengths This means the uncertainty on galaxy position becomes so large, matching on galaxy position alone is no longer appropriate. We show how physical models such as those that exist for Body mass index, can be used in the field of record linkage
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
