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Three-Dimensional Printing Applications in Percutaneous Structural Heart Interventions.

Serge C Harb1, Leonardo L Rodriguez1, Marija Vukicevic2

  • 1Department of Cardiology, Cleveland Clinic, OH (S.C.H., L.L.R., S.R.K.).

Circulation. Cardiovascular Imaging
|October 10, 2019
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Summary
This summary is machine-generated.

Cardiovascular 3D printing creates patient-specific heart models from medical scans. These models enhance understanding, improve procedural planning, and aid communication in cardiology, especially for structural interventions.

Keywords:
echocardiographyheart diseaseprintingtomographyworkflow

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Area of Science:

  • Cardiovascular medicine
  • Medical imaging
  • Biomedical engineering

Background:

  • Cardiovascular 3D printing fabricates patient-specific cardiac replicas using volumetric imaging data.
  • Echocardiography, CT, and MRI are key imaging modalities for data acquisition.
  • These replicas offer advanced visualization and anatomical understanding.

Purpose of the Study:

  • To review the process and workflow of cardiovascular 3D printing.
  • To discuss cardiac applications, particularly in structural interventions.
  • To highlight the role of 3D printed models in procedural planning.

Main Methods:

  • Summarizing the workflow from imaging acquisition to 3D model generation.
  • Reviewing literature on cardiac applications of 3D printing.
  • Focusing on the use in percutaneous structural interventions.

Main Results:

  • 3D printing enhances visualization and understanding of cardiac anatomy.
  • It improves procedural planning and allows for interventional simulation.
  • Models are valuable for patient and trainee communication.

Conclusions:

  • Cardiovascular 3D printing is broadly used across congenital, vascular, and valvular diseases.
  • It is particularly impactful in structural heart interventions.
  • Procedural planning for these interventions increasingly relies on 3D printed models.