Abstract

There is family aggregation of obstructive sleep apnea (OSA) as has been shown in the United States, Europe and recently in Iceland. Iceland represents a unique opportunity for genetic research. It is a community that was settled by founders in the 9 th Century, and has developed in relative isolation since that time to its present size of 285,000 persons. Moreover, there is a commitment to record keeping that has allowed deCODE Genetics, who are collaborators on this grant, to develop a computerized genealogy data base that permits the ancestry of individuals to be traced over centuries. This tool, together with the founder nature of the population, makes possible a unique genealogy-driven approach to study the genetics of complex disorders, an approach that has already been successful. We propose in this application to study the genetic basis of the common disorder---obstructive sleep apnea--using this genealogical approach. The study will be built on patients with the disorder, who have already been diagnosed in Iceland and where large family pedigrees have been identified. The proposed study involves a genome-wide family linkage investigation. This will be conducted with an affected only approach examining allele sharing between affected individuals using 1,100 markers spaced across the genome. We plan to oversample the relatively non-obese subjects providing us the opportunity to evaluate linkage in both relatively non-obese and obese subjects. The linkage study will be complemented with an association study, with unrelated cases and controls, matched for age, gender, and menopausal status. In the association study, we will, as a primary aim, test candidate genes arising from the linkage study and, as a secondary aim, evaluate candidate genes that we believe will be identified in the ongoing Cleveland Family Study. A subset of subjects in both the family linkage and association study, will have in-depth phenotyping to determine whether there are sub-phenotypes for this complex disorder and, if so, whether they aggregate in families. This in depth phenotyping will involve upper airway magnetic resonance imaging to evaluate upper airway soft tissue and craniofacial structures, acoustic rhinometry to quantify nasal resistance, a known risk factor for the disorder, and insulin resistance. We will explore whether there are distinct patterns of linkage for the different sub-phenotypes. To accomplish this large genetic study, we have put together the resources of three major organizations--the University of Pennsylvania, the University of Iceland Hospitals, and deCODE Genetics. We propose to leverage the truly unique infrastructure developed by deCODE Genetics, the clinical research programs in sleep apnea at the University of Iceland Hospitals, and the in-depth phenotyping expertise at the University of Pennsylvania to accomplish our goals.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL072067-03
Application #
6942429
Study Section
Epidemiology and Disease Control Subcommittee 2 (EDC)
Program Officer
Twery, Michael
Project Start
2003-09-30
Project End
2008-07-31
Budget Start
2005-08-01
Budget End
2006-07-31
Support Year
3
Fiscal Year
2005
Total Cost
$1,169,711
Indirect Cost

  Institution

Name
University of Pennsylvania
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
042250712
City
Philadelphia
State
PA
Country
United States
Zip Code
19104

  Publications

Värendh, Maria; Andersson, Morgan; Bjørnsdottir, Erla et al. (2018) Nocturnal nasal obstruction is frequent and reduces sleep quality in patients with obstructive sleep apnea. J Sleep Res 27:e12631
Eysteinsdottir, Bjorg; Gislason, Thorarinn; Pack, Allan I et al. (2017) Insomnia complaints in lean patients with obstructive sleep apnea negatively affect positive airway pressure treatment adherence. J Sleep Res 26:159-165
Bjornsdottir, Erla; Keenan, Brendan T; Eysteinsdottir, Bjorg et al. (2015) Quality of life among untreated sleep apnea patients compared with the general population and changes after treatment with positive airway pressure. J Sleep Res 24:328-38
Arnardottir, Erna S; Lim, Diane C; Keenan, Brendan T et al. (2015) Effects of obesity on the association between long-term sleep apnea treatment and changes in interleukin-6 levels: the Icelandic Sleep Apnea Cohort. J Sleep Res 24:148-59
Pak, V M; Keenan, B T; Jackson, N et al. (2015) Adhesion molecule increases in sleep apnea: beneficial effect of positive airway pressure and moderation by obesity. Int J Obes (Lond) 39:472-9
Ye, Lichuan; Pien, Grace W; Ratcliffe, Sarah J et al. (2014) The different clinical faces of obstructive sleep apnoea: a cluster analysis. Eur Respir J 44:1600-7
Arnardottir, E S; Maislin, G; Jackson, N et al. (2013) The role of obesity, different fat compartments and sleep apnea severity in circulating leptin levels: the Icelandic Sleep Apnea Cohort study. Int J Obes (Lond) 37:835-42
Björnsdóttir, Erla; Janson, Christer; Sigurdsson, Jón F et al. (2013) Symptoms of insomnia among patients with obstructive sleep apnea before and after two years of positive airway pressure treatment. Sleep 36:1901-9
Maislin, Greg; Ahmed, Murtuza M; Gooneratne, Nalaka et al. (2012) Single slice vs. volumetric MR assessment of visceral adipose tissue: reliability and validity among the overweight and obese. Obesity (Silver Spring) 20:2124-32
Bjornsdottir, Erla; Janson, Christer; Gislason, Thorarinn et al. (2012) Insomnia in untreated sleep apnea patients compared to controls. J Sleep Res 21:131-8

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