The German AugUR study: study protocol of a prospective study to investigate chronic diseases in the elderly

Stark, Klaus; Olden, Matthias; Brandl, Caroline; Dietl, Alexander; Zimmermann, Martina E.; Schelter, Sabine C.; Loss, Julika; Leitzmann, Michael F.; Böger, Carsten A.; Luchner, Andreas; Kronenberg, Florian; Helbig, Horst; Weber, Bernhard H. F.; Heid, Iris M.

doi:10.1186/s12877-015-0122-0

Cited by 34 publications

(70 citation statements)

References 29 publications

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“…(1) Using LD-score regression ((LDSC)) 32 , we estimated the additive contribution of all analyzed variants, i.e., narrow-sense heritability, h 2 =13.4% (based on unrelated individuals of European-ancestry from UKB, N = 364,674, Table 5). (4) Finally, we observed significant and very similar GRS effects across two studies, in UKB as the largest source of our GWAS and in AugUR 34 as an independent population-based study (UKB, bGRS=-0.24 ml/min/1.73m 2 per allele, PGRS = 6.7 x 10 -5847 ; AugUR, bGRS=-0.21 ml/min/1.73m 2 per allele, PGRS = 1.6 x 10 -9 ; Table 4). In AugUR, individuals with a high versus low genetic risk (95% percentile of GRS versus 5%, i.e.…”

Section: Aggregated Genetic Impact On Egfrcreasupporting

confidence: 70%

“…To estimate an average and cumulative effect of genetic variants on eGFRcrea, we conducted GRS analyses in two studies: The German AugUR study (prospective study in the mobile elderly general population around Regensburg, Germany, age range 70-95y, mean +/-SD eGFRcrea = 70.0 +/-15.5 ml/min/1.73m 2 , n = 1,105) 34 , and UKB (prospective cohort study from UK, age range 40-69y, mean +/-SD eGFRcrea = 90.6 +/-13.2 ml/min/1.73m 2 , n ~ 500,000) 14 . While UKB was part of our variant identifying discovery meta-analysis, AugUR…”

Section: Genetic Risk Score Analysesmentioning

confidence: 99%

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Discovery and prioritization of variants and genes for kidney function in >1.2 million individuals

Stanzick

Kronenberg

et al. 2020

Preprint

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Chronic kidney disease (CKD) has a complex genetic underpinning. Genome-wide association studies (GWAS) of CKD-defining glomerular filtration rate (GFR) have identified hundreds of loci, but prioritization of variants and genes is challenging. To expand and refine GWAS discovery, we meta-analyzed GWAS data for creatinine-based estimated GFR (eGFRcrea) from the Chronic Kidney Disease Genetics Consortium (CKDGen, n=765,348, trans-ethnic) and UK Biobank (UKB, n=436,581, Europeans). The results (i) extend the number of eGFRcrea loci (424 loci; 201 novel; 8.9% eGFRcrea variance explained by 634 independent signals); (ii) improve fine-mapping resolution (138 99% credible sets with ≤5 variants, 44 single-variant sets); (iii) ascertain likely kidney function relevance for 343 loci (consistent association with alternative biomarkers); and (iv) highlight 34 genes with strong evidence by a systematic Gene PrioritiSation (GPS). We provide a sortable, searchable and customizable GPS tool to navigate through the in silico functional evidence and select relevant targets for functional investigations.

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Section: Aggregated Genetic Impact On Egfrcreasupporting

confidence: 70%

Section: Genetic Risk Score Analysesmentioning

confidence: 99%

Discovery and prioritization of variants and genes for kidney function in >1.2 million individuals

Stanzick

Kronenberg

et al. 2020

Preprint

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“…Detailed information on this data can be found in Stark et al. (). Briefly, the AugUR study is a prospective study in the elderly population in the city and county of Regensburg in Eastern Bavaria, Germany.…”

Section: Example: Maximum Likelihood Approach Applied To Cross‐sectiomentioning

confidence: 99%

“…We derive the model‐based conditional probability of disease in randomly selected single entities and propose to optimise a likelihood based on the derived conditional probabilities to estimate regression parameters. In Section 2.3, we discuss additional misclassification in the single entity disease diagnosis and, in Sections 3 and 4, we compare the different estimation approaches in a real data example of the AugUR study on AMD (Age‐related diseases: Understanding genetic and nongenetic influences—a study at the University of Regensburg, Stark et al., ) and based on simulated data. In Section 5, we discuss the proposed modelling approach and its assumptions and give recommendations for application.…”

Section: Introductionmentioning

confidence: 99%

Response misclassification in studies on bilateral diseases

et al. 2019

Self Cite

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Misclassification in binary outcomes can severely bias effect estimates of regression models when the models are naively applied to error‐prone data. Here, we discuss response misclassification in studies on the special class of bilateral diseases. Such diseases can affect neither, one, or both entities of a paired organ, for example, the eyes or ears. If measurements are available on both organ entities, disease occurrence in a person is often defined as disease occurrence in at least one entity. In this setting, there are two reasons for response misclassification: (a) ignorance of missing disease assessment in one of the two entities and (b) error‐prone disease assessment in the single entities. We investigate the consequences of ignoring both types of response misclassification and present an approach to adjust the bias from misclassification by optimizing an adequate likelihood function. The inherent modelling assumptions and problems in case of entity‐specific misclassification are discussed. This work was motivated by studies on age‐related macular degeneration (AMD), a disease that can occur separately in each eye of a person. We illustrate and discuss the proposed analysis approach based on real‐world data of a study on AMD and simulated data.

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“…We developed a software program that guarantees unique IDs, supports the generation of structured IDs to facilitate study organization, provides layered IDs to enhance data protection, and can extend existing IDs with new non-overlapping batches. While IDGenerator was originally developed for the needs of the AugUR study [ 13 ], it allows for different parametrization and therefore can be applied to epidemiological studies with different requirements.…”

Section: Introductionmentioning

confidence: 99%

IDGenerator: unique identifier generator for epidemiologic or clinical studies

Olden

Holle

Heid

et al. 2016

BMC Med Res Methodol

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BackgroundCreating study identifiers and assigning them to study participants is an important feature in epidemiologic studies, ensuring the consistency and privacy of the study data. The numbering system for identifiers needs to be random within certain number constraints, to carry extensions coding for organizational information, or to contain multiple layers of numbers per participant to diversify data access. Available software can generate globally-unique identifiers, but identifier-creating tools meeting the special needs of epidemiological studies are lacking. We have thus set out to develop a software program to generate IDs for epidemiological or clinical studies.ResultsOur software IDGenerator creates unique identifiers that not only carry a random identifier for a study participant, but also support the creation of structured IDs, where organizational information is coded into the ID directly. This may include study center (for multicenter-studies), study track (for studies with diversified study programs), or study visit (baseline, follow-up, regularly repeated visits). Our software can be used to add a check digit to the ID to minimize data entry errors. It facilitates the generation of IDs in batches and the creation of layered IDs (personal data ID, study data ID, temporary ID, external data ID) to ensure a high standard of data privacy. The software is supported by a user-friendly graphic interface that enables the generation of IDs in both standard text and barcode 128B format.ConclusionOur software IDGenerator can create identifiers meeting the specific needs for epidemiologic or clinical studies to facilitate study organization and data privacy. IDGenerator is freeware under the GNU General Public License version 3; a Windows port and the source code can be downloaded at the Open Science Framework website: https://osf.io/urs2g/.

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The German AugUR study: study protocol of a prospective study to investigate chronic diseases in the elderly

Cited by 34 publications

References 29 publications

Discovery and prioritization of variants and genes for kidney function in >1.2 million individuals

Discovery and prioritization of variants and genes for kidney function in >1.2 million individuals

Response misclassification in studies on bilateral diseases

IDGenerator: unique identifier generator for epidemiologic or clinical studies

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