Shaping the Future of Cardiovascular Disease by 3D Printing Applications in Stent Technology and its Clinical Outcomes

Ullah, Muneeb; Bibi, Ayisha; Wahab, Abdul; Hamayun, Shah; Rehman, Mahboob Ur; Khan, Shahid Ullah; Awan, Uzma Azeem; Riaz, Noor-ul-ain; Naeem, Muhammad; Saeed, Sumbul; Hussain, Talib

doi:10.1016/j.cpcardiol.2023.102039

Cited by 5 publications

(4 citation statements)

References 175 publications

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“…It has been reported that 3D-printed devices including stents and valves have improved vessel patency and quality of life in cases of pulmonary stenosis, coronary stenotic lesions, and complex valve pathologies [104,107,110,112,[117][118][119]141,142]. The factors that affect the long-term safety of using 3D-printed devices to model stents in patients with coronary artery disease, which include biocompatibility, thrombosis, degradation and mechanical stability, long-term durability and performance, vessel injury, adverse events and complications, patient suitability, and anatomical variability, should be considered [54,143]. Three-dimensional bioprinting is a promising technology advancing the applications of 3D-printed models to another level, although most of the current applications of 3D bioprinting in cardiovascular disease are still in their early stages of development [144].…”

Section: The Use Of 3d-printed Devices In Treating Cardiovascular Dis...mentioning

confidence: 99%

Cardiovascular Computed Tomography in the Diagnosis of Cardiovascular Disease: Beyond Lumen Assessment

Sun,

Silberstein,

Vaccarezza

2024

JCDD

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Cardiovascular CT is being widely used in the diagnosis of cardiovascular disease due to the rapid technological advancements in CT scanning techniques. These advancements include the development of multi-slice CT, from early generation to the latest models, which has the capability of acquiring images with high spatial and temporal resolution. The recent emergence of photon-counting CT has further enhanced CT performance in clinical applications, providing improved spatial and contrast resolution. CT-derived fractional flow reserve is superior to standard CT-based anatomical assessment for the detection of lesion-specific myocardial ischemia. CT-derived 3D-printed patient-specific models are also superior to standard CT, offering advantages in terms of educational value, surgical planning, and the simulation of cardiovascular disease treatment, as well as enhancing doctor–patient communication. Three-dimensional visualization tools including virtual reality, augmented reality, and mixed reality are further advancing the clinical value of cardiovascular CT in cardiovascular disease. With the widespread use of artificial intelligence, machine learning, and deep learning in cardiovascular disease, the diagnostic performance of cardiovascular CT has significantly improved, with promising results being presented in terms of both disease diagnosis and prediction. This review article provides an overview of the applications of cardiovascular CT, covering its performance from the perspective of its diagnostic value based on traditional lumen assessment to the identification of vulnerable lesions for the prediction of disease outcomes with the use of these advanced technologies. The limitations and future prospects of these technologies are also discussed.

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Section: The Use Of 3d-printed Devices In Treating Cardiovascular Dis...mentioning

confidence: 99%

Cardiovascular Computed Tomography in the Diagnosis of Cardiovascular Disease: Beyond Lumen Assessment

Sun,

Silberstein,

Vaccarezza

2024

JCDD

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“…Conventional treatments, including medications, surgery, and interventional procedures, can only provide relief from clinical symptoms but do not fundamentally address the issue. In the field of regenerative medicine, 3D printing technology represents a significant opportunity, as 3D-printed implantable organs hold the potential to contribute to saving more lives [210]. Maiullari et al [197] employed a bio-ink composed of PEGfibrinogen (PEG-PF) and sodium alginate (PEG-PF/Alg), along with human umbilical vein endothelial cells (HUVECs) and patient-specific induced pluripotent stem cells (iPSC-CMs) encapsulated within the bio-ink.…”

Section: Cardiovascular Tissue Engineeringmentioning

confidence: 99%

“…ogy represents a significant opportunity, as 3D-printed implantable organs hold the potential to contribute to saving more lives [210]. Maiullari et al [197] employed a bio-ink composed of PEG-fibrinogen (PEG-PF) and sodium alginate (PEG-PF/Alg), along with human umbilical vein endothelial cells (HUVECs) and patient-specific induced pluripotent stem cells (iPSC-CMs) encapsulated within the bio-ink.…”

Section: Cardiovascular Tissue Engineeringmentioning

confidence: 99%

Applications of Light-Based 3D Bioprinting and Photoactive Biomaterials for Tissue Engineering

Zhang,

et al. 2023

Materials

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The emergence of additive manufacturing, commonly referred to as 3D printing, has led to a revolution in the field of biofabrication. Numerous types of 3D bioprinting, including extrusion bioprinting, inkjet bioprinting, and lithography-based bioprinting, have been developed and have played pivotal roles in driving a multitude of pioneering breakthroughs in the fields of tissue engineering and regenerative medicine. Among all the 3D bioprinting methods, light-based bioprinting utilizes light to crosslink or solidify photoreactive biomaterials, offering unprecedented spatiotemporal control over biomaterials and enabling the creation of 3D structures with extremely high resolution and precision. However, the lack of suitable photoactive biomaterials has hindered the application of light-based bioprinting in tissue engineering. The development of photoactive biomaterials has only recently been expanded. Therefore, this review summarizes the latest advancements in light-based 3D bioprinting technologies, including the development of light-based bioprinting techniques, photo-initiators (PIs), and photoactive biomaterials and their corresponding applications. Moreover, the challenges facing bioprinting are discussed, and future development directions are proposed.

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“…Transportation benefits from PBF's ability to manufacture custom components, enhancing vehicle performance and safety [40]. In the biomedical realm, it enables the production of patient-specific implants and prosthetics, revolutionizing healthcare [41,42]. Moreover, PBF technology has applications in the automotive industry, where it aids in crafting lightweight, durable parts, as well as in the jewelry industry for crafting intricate designs.…”

Section: Selective Laser Melting For Thin-walled Partsmentioning

confidence: 99%

Critical Review of Comparative Study of Selective Laser Melting and Investment Casting for Thin-Walled Parts

Dejene,

Lemu,

Gutema

2023

Materials

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Thin-walled structures are a significant and growing portion of engineering construction, with a wide range of applications, including storage vessels, industrial buildings, warehouses, aircraft, automobiles, bridges, ships, and oil rigs. Thin-walled components with minimum thickness without compromising strength and other quality characteristics are the desire of modern industry. Reducing wall thickness not only aids in lowering the cost of production. It also improves the effectiveness of engineering systems, resulting in lower fuel consumption and lower emissions of hazardous gases to the environment. Nowadays, even though thin-walled parts are demanded, the constraints of the production process, quality, and reliability are the concerns of current research and development. The ability to produce parts with intricate geometries and tight dimensional tolerances are important criteria for advanced manufacturing processes. In the early days of society, investment casting was used to produce jewelry, weapons, and statues. In modern industry, investment casting is still used to produce thin-walled and intricate parts such as turbine blades. The current advancements in SLM, which has the capacity to produce thin-walled and intricate parts, have recently attracted attention due to several benefits, such as the supreme degree of design freedom and the viability of tool-free production directly from CAD data. However, the current technological applications of SLM and investment casting are crucial for producing parts at the desired quality and reliability. This review article focuses on comparative studies of SLM and investment casting at the current technology level. The basis of comparison via systematic approach is mechanical characterization; quality in terms of porosity, microstructure, surface roughness and dimensional accuracy; and residual stress. Therefore, the latest open scientific sources published are considered to obtain sufficient literature coverage. Better tensile strength and fine microstructure are found in SLM, while better surface quality, fatigue load resistance, ductility, and residual stress are found in investment casting. The research gap for further investigation is indicated.

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Shaping the Future of Cardiovascular Disease by 3D Printing Applications in Stent Technology and its Clinical Outcomes

Cited by 5 publications

References 175 publications

Cardiovascular Computed Tomography in the Diagnosis of Cardiovascular Disease: Beyond Lumen Assessment

Cardiovascular Computed Tomography in the Diagnosis of Cardiovascular Disease: Beyond Lumen Assessment

Applications of Light-Based 3D Bioprinting and Photoactive Biomaterials for Tissue Engineering

Critical Review of Comparative Study of Selective Laser Melting and Investment Casting for Thin-Walled Parts

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