Genetic architecture of cardiac dynamic flow volumes

Bruna Gomes; Aditya Singh; Jack W. O’Sullivan; Theresia M. Schnurr; Pagé C. Goddard; Shaun Loong; David Amar; J. Weston Hughes; Mykhailo Kostur; Francois Haddad; Michael Salerno; Roger Foo; Stephen B. Montgomery; Victoria N. Parikh; Benjamin Meder; Euan A. Ashley

doi:10.1038/s41588-023-01587-5

Genetic architecture of cardiac dynamic flow volumes

Bruna Gomes, Aditya Singh, Jack W. O’Sullivan, Theresia M. Schnurr, Pagé C. Goddard, Shaun Loong, David Amar, J. Weston Hughes, Mykhailo Kostur, Francois Haddad, Michael Salerno, Roger Foo, Stephen B. Montgomery, Victoria N. Parikh, Benjamin Meder, Euan A. Ashley

Research output: Contribution to journal › Article › peer-review

Abstract

Cardiac blood flow is a critical determinant of human health. However, the definition of its genetic architecture is limited by the technical challenge of capturing dynamic flow volumes from cardiac imaging at scale. We present DeepFlow, a deep-learning system to extract cardiac flow and volumes from phase-contrast cardiac magnetic resonance imaging. A mixed-linear model applied to 37,653 individuals from the UK Biobank reveals genome-wide significant associations across cardiac dynamic flow volumes spanning from aortic forward velocity to aortic regurgitation fraction. Mendelian randomization reveals a causal role for aortic root size in aortic valve regurgitation. Among the most significant contributing variants, localizing genes (near ELN, PRDM6 and ADAMTS7) are implicated in connective tissue and blood pressure pathways. Here we show that DeepFlow cardiac flow phenotyping at scale, combined with genotyping data, reinforces the contribution of connective tissue genes, blood pressure and root size to aortic valve function.

Original language	English
Pages (from-to)	245-257
Number of pages	13
Journal	Nature Genetics
Volume	56
Issue number	2
DOIs	https://doi.org/10.1038/s41588-023-01587-5
State	Published - Feb 2024
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

All Science Journal Classification (ASJC) codes

Genetics

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10.1038/s41588-023-01587-5

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title = "Genetic architecture of cardiac dynamic flow volumes",

abstract = "Cardiac blood flow is a critical determinant of human health. However, the definition of its genetic architecture is limited by the technical challenge of capturing dynamic flow volumes from cardiac imaging at scale. We present DeepFlow, a deep-learning system to extract cardiac flow and volumes from phase-contrast cardiac magnetic resonance imaging. A mixed-linear model applied to 37,653 individuals from the UK Biobank reveals genome-wide significant associations across cardiac dynamic flow volumes spanning from aortic forward velocity to aortic regurgitation fraction. Mendelian randomization reveals a causal role for aortic root size in aortic valve regurgitation. Among the most significant contributing variants, localizing genes (near ELN, PRDM6 and ADAMTS7) are implicated in connective tissue and blood pressure pathways. Here we show that DeepFlow cardiac flow phenotyping at scale, combined with genotyping data, reinforces the contribution of connective tissue genes, blood pressure and root size to aortic valve function.",

author = "Bruna Gomes and Aditya Singh and O{\textquoteright}Sullivan, {Jack W.} and Schnurr, {Theresia M.} and Goddard, {Pag{\'e} C.} and Shaun Loong and David Amar and Hughes, {J. Weston} and Mykhailo Kostur and Francois Haddad and Michael Salerno and Roger Foo and Montgomery, {Stephen B.} and Parikh, {Victoria N.} and Benjamin Meder and Ashley, {Euan A.}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature America, Inc. 2023.",

year = "2024",

month = feb,

doi = "10.1038/s41588-023-01587-5",

language = "الإنجليزيّة",

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T1 - Genetic architecture of cardiac dynamic flow volumes

AU - Gomes, Bruna

AU - Singh, Aditya

AU - O’Sullivan, Jack W.

AU - Schnurr, Theresia M.

AU - Goddard, Pagé C.

AU - Loong, Shaun

AU - Amar, David

AU - Hughes, J. Weston

AU - Kostur, Mykhailo

AU - Haddad, Francois

AU - Salerno, Michael

AU - Foo, Roger

AU - Montgomery, Stephen B.

AU - Parikh, Victoria N.

AU - Meder, Benjamin

AU - Ashley, Euan A.

PY - 2024/2

Y1 - 2024/2

N2 - Cardiac blood flow is a critical determinant of human health. However, the definition of its genetic architecture is limited by the technical challenge of capturing dynamic flow volumes from cardiac imaging at scale. We present DeepFlow, a deep-learning system to extract cardiac flow and volumes from phase-contrast cardiac magnetic resonance imaging. A mixed-linear model applied to 37,653 individuals from the UK Biobank reveals genome-wide significant associations across cardiac dynamic flow volumes spanning from aortic forward velocity to aortic regurgitation fraction. Mendelian randomization reveals a causal role for aortic root size in aortic valve regurgitation. Among the most significant contributing variants, localizing genes (near ELN, PRDM6 and ADAMTS7) are implicated in connective tissue and blood pressure pathways. Here we show that DeepFlow cardiac flow phenotyping at scale, combined with genotyping data, reinforces the contribution of connective tissue genes, blood pressure and root size to aortic valve function.

AB - Cardiac blood flow is a critical determinant of human health. However, the definition of its genetic architecture is limited by the technical challenge of capturing dynamic flow volumes from cardiac imaging at scale. We present DeepFlow, a deep-learning system to extract cardiac flow and volumes from phase-contrast cardiac magnetic resonance imaging. A mixed-linear model applied to 37,653 individuals from the UK Biobank reveals genome-wide significant associations across cardiac dynamic flow volumes spanning from aortic forward velocity to aortic regurgitation fraction. Mendelian randomization reveals a causal role for aortic root size in aortic valve regurgitation. Among the most significant contributing variants, localizing genes (near ELN, PRDM6 and ADAMTS7) are implicated in connective tissue and blood pressure pathways. Here we show that DeepFlow cardiac flow phenotyping at scale, combined with genotyping data, reinforces the contribution of connective tissue genes, blood pressure and root size to aortic valve function.

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U2 - 10.1038/s41588-023-01587-5

DO - 10.1038/s41588-023-01587-5

M3 - مقالة

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SN - 1061-4036

VL - 56

SP - 245

EP - 257

JO - Nature Genetics

JF - Nature Genetics

IS - 2

ER -

Genetic architecture of cardiac dynamic flow volumes

Abstract

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