A Standardized Hand Fracture Fixation Training Framework using Novel 3D Printed Ex Vivo Hand Models: Our Experience as a Unit

Papavasiliou, Theodora; Chatzimichail, Stelios; Chan, Jeff; Bain, Charles J.; Uppal, Lauren

doi:10.1097/gox.0000000000003406

Cited by 9 publications

(11 citation statements)

References 9 publications

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“…We’ve already seen a number of tremendous changes and improvements in orthopedic medical education brought about by different 3D technologies. Instead of displaying the different visual bibliometrics results from multiple perspectives which have already been shown in the result section, we also read and evaluate all the retrieved articles in detail extensively, 11 representative publications from three major branches of orthopedics were chosen ( Van Sint Jan et al, 2003 ; Podolsky et al, 2010 ; Gottschalk et al, 2015 ; Park et al, 2018 ; Mishra et al, 2019 ; Wang et al, 2019 ; Montgomery et al, 2020 ; Clifton et al, 2021 ; Foo et al, 2021 ; Kim et al, 2021 ; Papavasiliou et al, 2021 ), comprehensive evaluative analysis was made from basic information, purpose, assessments, results, benefits and limitations ( Table 1 , trauma surgery n = 4; Table 2 , joint surgery n = 3; Table 3 , spine surgery n = 4).…”

Section: Discussionmentioning

confidence: 99%

The Application of Three-Dimensional Technologies in the Improvement of Orthopedic Surgery Training and Medical Education Quality: A Comparative Bibliometrics Analysis

Shi

Cavagnaro

et al. 2022

Front. Bioeng. Biotechnol.

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Orthopedics is a medical specialty that focuses on the clinical treatment and care of the musculoskeletal system. Orthopedics is a medical specialty which specializing in the clinical treatment and nursing of musculoskeletal system. The education of orthopedics is often serious and difficult because of the high technical requirements, complicated anatomical knowledge and long study process. However, medical students or junior residents rarely have the opportunity to see such orthopedic surgery or attend preclinical practice, which limits the opportunities for training clinicians. Hopefully, with the increasing use of three-dimensional (3D) technologies in medical teaching, this situation can be alleviated. In this study, we demonstrate that different 3D technologies can effectively simulate orthopedic surgery with very high accuracy. We carefully evaluated the use of 3D technologies in primary medical teaching and proposed a vision for the future. We searched and screened 3,997 publications from the Web of Science Core Collection (WoSCC) on 22 Oct 2021 with (trauma) AND ((education) OR (training) OR (teaching) OR (learning)) AND ((3D) OR (Three Dimensional)), (Joint) AND ((education) OR (training) OR (teaching) OR (learning)) AND ((3D) OR (Three Dimensional)), (spine) AND ((education) OR (training) OR (teaching) OR (learning)) AND ((3D) OR (Three Dimensional)) as the search strategy. Then, we eliminated the publications irrelevant to “orthopedics” AND/OR “orthopaedic” (in United Kingdom English), the final number of publications are 440 for trauma surgery, 716 for joint surgery and 363 for spine surgery, a visual display of comprehensive information analysis was made by VOSviewer. Next, we read and analyzed retrieved articles extensively according to the selection criteria, 11 highly cited publications on three major branches of orthopedics were chosen. The extracted data included the authors, purpose, methods, results and benefits/limitations. The evaluation of these studies directly and objectively proved the superiority of 3D technologies in orthopedics. Furthermore, the material usage and strength of 3D technologies can be closer to the real situation, which will help improve their effectiveness in teaching. We hope that more relevant studies will be conducted to continue examining the effects of 3D technologies on orthopedic medical education as well as orthopedic surgery training, and we hope that this technique can be more widely used in the clinical teaching of orthopedics to train clinicians on learning medical theory and surgical technology quickly and efficiently.

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Section: Discussionmentioning

confidence: 99%

The Application of Three-Dimensional Technologies in the Improvement of Orthopedic Surgery Training and Medical Education Quality: A Comparative Bibliometrics Analysis

Shi

Cavagnaro

et al. 2022

Front. Bioeng. Biotechnol.

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“… 4 Three-dimensional printed models are particularly of great interest to early learning curve trainees given that it enables the practice of technically challenging procedures in inconsequential environments. 10 As a result, models have become increasingly important components of microsurgical training. As the standardization of microsurgical training models shifts towards the chicken thigh model, there is a need to ensure high-quality simulation that hinges on the accessibility, reliability, and availability of models.…”

Section: Discussionmentioning

confidence: 99%

3D Printed Chest Wall: A Tool for Advanced Microsurgical Training Simulating Depth and Limited View

Papavasiliou

Ubong

Khajuria

et al. 2021

Plastic and Reconstructive Surgery - Global Open

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Summary: The deep inferior epigastric perforator (DIEP) flap has become the free flap of choice for autologous breast reconstruction. However, anastomoses of DIEP pedicles to internal mammary vessels in the chest wall are difficult due to restricted access and the depth of the vessels. Successful performance of such demanding procedures necessitates advanced requirements for microsurgical training models. The current chicken thigh model has been used to acquire microsurgical skills, allowing early learning curve trainees to practice repeatedly in inconsequential environments. Despite the increasing use of this model for training purposes, the resemblance to a clinical environment is tenuous. Such models should include anastomosis practice within the depth where the recipient vessels are located. To address this, we developed a three-dimensional (3D) printed chest wall as an addition to the current chicken thigh model, which reliably mimics the complexity of the anastomosis performed during DIEP breast reconstruction. This form of rapid prototyping facilitates a newfound ability for early learning curve trainees to exercise end-to-end anastomoses on vessels located with variable depths. Our enhancement of the current chicken thigh model is simple, cost-effective and offers a significantly more realistic resemblance to a clinical situation.

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“…Both groups watched an initial lecture component, group 1 (control) in person and group 2 (intervention) from home. Group 1 performed the practical part of the course on 3D printed hands (Stelth Ltd) [11] and then performed an assessed component of K wiring a 5 th metacarpal neck fracture. Group 2 then attended for the practical as above, but with a 10-min meditation (Headspace®, California, with permission) immediately before the assessment.…”

Section: Methodsmentioning

confidence: 99%

Implementing mindfulness meditation in hand surgery training: a feasibility study

et al. 2022

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A Standardized Hand Fracture Fixation Training Framework using Novel 3D Printed Ex Vivo Hand Models: Our Experience as a Unit

Cited by 9 publications

References 9 publications

The Application of Three-Dimensional Technologies in the Improvement of Orthopedic Surgery Training and Medical Education Quality: A Comparative Bibliometrics Analysis

The Application of Three-Dimensional Technologies in the Improvement of Orthopedic Surgery Training and Medical Education Quality: A Comparative Bibliometrics Analysis

3D Printed Chest Wall: A Tool for Advanced Microsurgical Training Simulating Depth and Limited View

Implementing mindfulness meditation in hand surgery training: a feasibility study

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