Color-coded patient-specific physical models of congenital heart disease

Purpose – The purpose of this study was to develop and apply new physical heart defect models (PHDMs) that are patient-specific and color-coded with an optimized map. Design/methodology/approach – Heart defect anatomies were segmented from medical images and reconstructed to form virtual models, whi...

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Bibliographic Details
Published in:Rapid prototyping journal 2014-06, Vol.20 (4), p.336-343
Main Authors: Ejaz, Fariha, Ryan, Justin, Henriksen, Megan, Stomski, Lillee, Feith, Megan, Osborn, Michele, Pophal, Stephen, Richardson, Randy, Frakes, David
Format: Article
Language:English
Subjects:
Aids
Blood
Cardiovascular disease
Color
Coronary vessels
Defects
Education
Effectiveness
Engineering
Heart
Heart diseases
Industrial engineering, design & manufacturing
Medical
Medical education
Medical students
Mortality
Pulmonary arteries
Rapid prototyping
Software
Studies
Surgeons
Telemedicine
Veins & arteries
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Description
Summary:Purpose – The purpose of this study was to develop and apply new physical heart defect models (PHDMs) that are patient-specific and color-coded with an optimized map. Design/methodology/approach – Heart defect anatomies were segmented from medical images and reconstructed to form virtual models, which were then color-coded and rapid prototyped. The resulting PHDMs were used in a medical educational study to evaluate their pedagogical efficacy and in clinical case studies to investigate their utility in surgical planning. Findings – A growing library of 36 PHDMs (including the most common defects) was generated. Results from the educational study showed that the PHDMs enabled uniquely effective learning, and the clinical case studies indicated that the models added value as surgical planning aids. Research limitations/implications – The education study involved a limited number of students, so future work should consider a larger sample size. The clinical case studies favored use of the PHDMs in surgical planning, but provided only qualitative support. Practical implications – Workflow optimization is critical for PHDMs to be used effectively in surgical planning because some operations must be performed in emergently. Social implications – Because PHDMs have potential to influence surgeons’ actions as surgical planning aids, their use in that context must be thoroughly vetted. Originality/value – The proposed models represent the first PHDMs that are patient-specific and fully color-coded with a standardized map optimized for the human visual system. The models enhanced medical education and facilitated effective surgical planning in this study.
ISSN:1355-2546
1758-7670
DOI:10.1108/RPJ-11-2012-0105