Physical and Computational Modeling for Transcatheter Structural Heart Interventions

Nadeen N. Faza; Serge C. Harb; Dee Dee Wang; Mark M.P. van den Dorpel; Nicolas Van Mieghem; Stephen H. Little

doi:10.1016/j.jcmg.2024.01.014

Physical and Computational Modeling for Transcatheter Structural Heart Interventions

Nadeen N. Faza
, Serge C. Harb
, Dee Dee Wang
, Mark M.P. van den Dorpel
, Nicolas Van Mieghem
, Stephen H. Little^*

^*Corresponding author for this work

Cardiology

Research output: Contribution to journal › Review article › Academic › peer-review

13 Citations (Scopus)

28 Downloads (Pure)

Abstract

Structural heart disease interventions rely heavily on preprocedural planning and simulation to improve procedural outcomes and predict and prevent potential procedural complications. Modeling technologies, namely 3-dimensional (3D) printing and computational modeling, are nowadays increasingly used to predict the interaction between cardiac anatomy and implantable devices. Such models play a role in patient education, operator training, procedural simulation, and appropriate device selection. However, current modeling is often limited by the replication of a single static configuration within a dynamic cardiac cycle. Recognizing that health systems may face technical and economic limitations to the creation of “in-house” 3D-printed models, structural heart teams are pivoting to the use of computational software for modeling purposes.

Original language	English
Pages (from-to)	428-440
Number of pages	13
Journal	JACC: Cardiovascular Imaging
Volume	17
Issue number	4
DOIs	https://doi.org/10.1016/j.jcmg.2024.01.014
Publication status	Published - Apr 2024

Bibliographical note

Publisher Copyright:
© 2024 American College of Cardiology Foundation

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10.1016/j.jcmg.2024.01.014

Physical and Computational Modeling for Transcatheter Structural Heart InterventionsFinal published version, 2.49 MBLicence: Article 25fa Dutch Copyright Act

Cite this

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title = "Physical and Computational Modeling for Transcatheter Structural Heart Interventions",

abstract = "Structural heart disease interventions rely heavily on preprocedural planning and simulation to improve procedural outcomes and predict and prevent potential procedural complications. Modeling technologies, namely 3-dimensional (3D) printing and computational modeling, are nowadays increasingly used to predict the interaction between cardiac anatomy and implantable devices. Such models play a role in patient education, operator training, procedural simulation, and appropriate device selection. However, current modeling is often limited by the replication of a single static configuration within a dynamic cardiac cycle. Recognizing that health systems may face technical and economic limitations to the creation of “in-house” 3D-printed models, structural heart teams are pivoting to the use of computational software for modeling purposes.",

author = "Faza, \{Nadeen N.\} and Harb, \{Serge C.\} and Wang, \{Dee Dee\} and \{van den Dorpel\}, \{Mark M.P.\} and \{Van Mieghem\}, Nicolas and Little, \{Stephen H.\}",

note = "Publisher Copyright: {\textcopyright} 2024 American College of Cardiology Foundation",

year = "2024",

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AU - Harb, Serge C.

AU - Wang, Dee Dee

AU - van den Dorpel, Mark M.P.

AU - Van Mieghem, Nicolas

AU - Little, Stephen H.

PY - 2024/4

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N2 - Structural heart disease interventions rely heavily on preprocedural planning and simulation to improve procedural outcomes and predict and prevent potential procedural complications. Modeling technologies, namely 3-dimensional (3D) printing and computational modeling, are nowadays increasingly used to predict the interaction between cardiac anatomy and implantable devices. Such models play a role in patient education, operator training, procedural simulation, and appropriate device selection. However, current modeling is often limited by the replication of a single static configuration within a dynamic cardiac cycle. Recognizing that health systems may face technical and economic limitations to the creation of “in-house” 3D-printed models, structural heart teams are pivoting to the use of computational software for modeling purposes.

AB - Structural heart disease interventions rely heavily on preprocedural planning and simulation to improve procedural outcomes and predict and prevent potential procedural complications. Modeling technologies, namely 3-dimensional (3D) printing and computational modeling, are nowadays increasingly used to predict the interaction between cardiac anatomy and implantable devices. Such models play a role in patient education, operator training, procedural simulation, and appropriate device selection. However, current modeling is often limited by the replication of a single static configuration within a dynamic cardiac cycle. Recognizing that health systems may face technical and economic limitations to the creation of “in-house” 3D-printed models, structural heart teams are pivoting to the use of computational software for modeling purposes.

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M3 - Review article

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EP - 440

JO - JACC: Cardiovascular Imaging

JF - JACC: Cardiovascular Imaging

IS - 4

ER -

Physical and Computational Modeling for Transcatheter Structural Heart Interventions

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