| dc.creator |
ACAR, SEZER |
|
| dc.creator |
Atar, Muge |
|
| dc.creator |
Ellard, Sian |
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| dc.creator |
Flanagan, Sarah E. |
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| dc.creator |
Johnson, Matthew B. |
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| dc.creator |
DEMİRBİLEK, HÜSEYİN |
|
| dc.creator |
Cizmecioglu, Filiz |
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| dc.creator |
BERBEROĞLU, MERİH |
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| dc.creator |
DEMİR, KORCAN |
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| dc.creator |
Houghton, Jayne |
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| dc.creator |
Patel, Kashyap A. |
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| dc.creator |
Catli, Gonul |
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| dc.creator |
Bas, Serpil |
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| dc.creator |
Ozbek, Mehmet N. |
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| dc.creator |
Yildiz, Melek |
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| dc.creator |
GÜRAN, TÜLAY |
|
| dc.creator |
Akcay, Teoman |
|
| dc.creator |
Kocyigit, Cemil |
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| dc.creator |
Hattersley, Andrew T. |
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| dc.creator |
Weedon, Michael N. |
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| dc.creator |
Colclough, Kevin |
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| dc.creator |
ŞIKLAR, ZEYNEP |
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| dc.date |
2022-02-01T00:00:00Z |
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| dc.identifier |
31398001-287b-4355-bba0-ec3b985caa39 |
|
| dc.identifier |
10.1007/s00125-021-05597-y |
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| dc.identifier |
https://avesis.sdu.edu.tr/publication/details/31398001-287b-4355-bba0-ec3b985caa39/oai |
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| dc.description |
Aims/hypothesis Current clinical guidelines for childhood-onset monogenic diabetes outside infancy are mainly focused on identifying and testing for dominantly inherited, predominantly MODY genes. There are no systematic studies of the recessively inherited causes of monogenic diabetes that are likely to be more common in populations with high rates of consanguinity. We aimed to determine the contribution of recessive causes of monogenic diabetes in paediatric diabetes clinics and to identify clinical criteria by which to select individuals for recessive monogenic diabetes testing. Methods We conducted a cross-sectional study of 1093 children from seven paediatric diabetes clinics across Turkey (a population with high rates of consanguinity). We undertook genetic testing of 50 known dominant and recessive causes of monogenic diabetes for 236 children at low risk of type 1 diabetes. As a comparison, we used monogenic diabetes cases from UK paediatric diabetes clinics (a population with low rates of consanguinity). Results Thirty-four children in the Turkish cohort had monogenic diabetes, equating to a minimal prevalence of 3.1%, similar to that in the UK cohort (p = 0.40). Forty-one per cent (14/34) had autosomal recessive causes in contrast to 1.6% (2/122) in the UK monogenic diabetes cohort (p < 0.0001). All conventional criteria for identifying monogenic diabetes (parental diabetes, not requiring insulin treatment, HbA(1c) <= 58 mmol/mol [<= 7.5%] and a composite clinical probability of MODY >10%) assisted the identification of the dominant (all p <= 0.0003) but not recessive cases (all p >= 0.2) in Turkey. The presence of certain non-autoimmune extra-pancreatic features greatly assisted the identification of recessive (p < 0.0001, OR 66.9) but not dominant cases. Conclusions/interpretation Recessively inherited mutations are a common cause of monogenic diabetes in populations with high rates of consanguinity. Present MODY-focused genetic testing strategies do not identify affected individuals. To detect all cases of monogenic paediatric diabetes, it is crucial that recessive genes are included in genetic panels and that children are selected for testing if they have certain non-autoimmune extra-pancreatic features in addition to current criteria. |
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| dc.language |
eng |
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| dc.rights |
info:eu-repo/semantics/closedAccess |
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| dc.title |
Systematic genetic testing for recessively inherited monogenic diabetes: a cross-sectional study in paediatric diabetes clinics |
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| dc.type |
info:eu-repo/semantics/article |
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