3D Printing in Eye Care

Larochelle, Ryan; Mann, Scott E.; Ifantides, Cristos

doi:10.1007/s40123-021-00379-6

Cited by 15 publications

(14 citation statements)

References 176 publications

(204 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Starting from magnetic resonance imaging or computer tomography, it is possible to achieve a 3D digital anatomical model and fabricate the final device, aiming to support better surgical planning and tissue regeneration [26][27][28]. The first approach is already used in different fields of surgery, such as cardiovascular [29], thoracic [30], facial plastic and reconstructive [31], eye care [32], otolaryngology [33], cranio-maxillofacial [34], cranial neurosurgery [35], spinal [36], and orthopaedic surgery [37] and has demonstrated the potential to reduce errors and costs. Hence, in the healthcare context, it is mandatory to evaluate AM families, select the technologies/materials able to reproduce the required medical device, and meet all of the governance requirements [38].…”

Section: D Printing and Bioprinting In The Healthcare Contextmentioning

confidence: 99%

Surgical Medical Education via 3D Bioprinting: Modular System for Endovascular Training

Foresti,

Fornasari,

Bianchini Massoni

et al. 2024

Bioengineering

View full text Add to dashboard Cite

There is currently a shift in surgical training from traditional methods to simulation-based approaches, recognizing the necessity of more effective and controlled learning environments. This study introduces a completely new 3D-printed modular system for endovascular surgery training (M-SET), developed to allow various difficulty levels. Its design was based on computed tomography angiographies from real patient data with femoro-popliteal lesions. The study aimed to explore the integration of simulation training via a 3D model into the surgical training curriculum and its effect on their performance. Our preliminary study included 12 volunteer trainees randomized 1:1 into the standard simulation (SS) group (3 stepwise difficulty training sessions) and the random simulation (RS) group (random difficulty of the M-SET). A senior surgeon evaluated and timed the final training session. Feedback reports were assessed through the Student Satisfaction and Self-Confidence in Learning Scale. The SS group completed the training sessions in about half time (23.13 ± 9.2 min vs. 44.6 ± 12.8 min). Trainees expressed high satisfaction with the training program supported by the M-SET. Our 3D-printed modular training model meets the current need for new endovascular training approaches, offering a customizable, accessible, and effective simulation-based educational program with the aim of reducing the time required to reach a high level of practical skills.

show abstract

Section: D Printing and Bioprinting In The Healthcare Contextmentioning

confidence: 99%

Surgical Medical Education via 3D Bioprinting: Modular System for Endovascular Training

Foresti,

Fornasari,

Bianchini Massoni

et al. 2024

Bioengineering

View full text Add to dashboard Cite

show abstract

“…Additionally, 3D printing could be employed for the development of highly accurate, individualized medical instruments [ 459 ]. Over the past 10 years, 3D printing has been heavily utilized in the fields of contact lens manufacturing, drug delivery to ocular tissues, implants, ocular research, and diagnostic models production [ 460 ].…”

Section: Long-acting Ocular Drug Delivery Devicesmentioning

confidence: 99%

Recent Advances of Ocular Drug Delivery Systems: Prominence of Ocular Implants for Chronic Eye Diseases

et al. 2023

View full text Add to dashboard Cite

Chronic ocular diseases can seriously impact the eyes and could potentially result in blindness or serious vision loss. According to the most recent data from the WHO, there are more than 2 billion visually impaired people in the world. Therefore, it is pivotal to develop more sophisticated, long-acting drug delivery systems/devices to treat chronic eye conditions. This review covers several drug delivery nanocarriers that can control chronic eye disorders non-invasively. However, most of the developed nanocarriers are still in preclinical or clinical stages. Long-acting drug delivery systems, such as inserts and implants, constitute the majority of the clinically used methods for the treatment of chronic eye diseases due to their steady state release, persistent therapeutic activity, and ability to bypass most ocular barriers. However, implants are considered invasive drug delivery technologies, especially those that are nonbiodegradable. Furthermore, in vitro characterization approaches, although useful, are limited in mimicking or truly representing the in vivo environment. This review focuses on long-acting drug delivery systems (LADDS), particularly implantable drug delivery systems (IDDS), their formulation, methods of characterization, and clinical application for the treatment of eye diseases.

show abstract

“…(15) IMPRESSÃO TRIDIMENSIONAL NA OFTALMOLOGIA O campo da oftalmologia começou a implantar a impressão tridimensional na área da educação por meio de modelos anatômicos, nos planejamentos cirúrgicos, em modelos de pesquisa, implantes, lentes, diagnósticos, aplicações terapêuticas e, mais recentemente, na proteção ocular durante a pandemia da doença pelo coronavírus 2019 (COVID-19). (16) Ela permite um desenho econômico e a produção de instrumentos que auxiliem na detecção precoce de condições oculares comuns, bem como o desenvolvimento de dispositivos diagnósticos e terapêuticos que podem ser personalizados. (1) Seu primeiro uso na área surgiu com modelos de cavidades orbitárias.…”

Section: Métodos De Impressão Tridimensionalunclassified