3D printing: potential clinical applications for personalised solid dose medications

2022 ◽  
Author(s):  
Liam Krueger ◽  
Jared A Miles ◽  
Kathryn J Steadman ◽  
Tushar Kumeria ◽  
Christopher R Freeman ◽  
...  
Keyword(s):  
3D Printing ◽  
Clinical Applications ◽  
Solid Dose

scholarly journals Alveolus Lung-on-a-Chip Platform: A Proposal

Chemosensors ◽  
2021 ◽  
Vol 9 (9) ◽  
pp. 248
Author(s):  
Noelia Campillo ◽  
Vinicius Rosa Oliveira ◽  
Renata Kelly da Palma
Keyword(s):  
Human Physiology ◽  
3D Printing ◽  
Respiratory Diseases ◽  
Animal Experiments ◽  
Clinical Applications ◽  
Potential Candidate ◽  
New Approaches ◽  
The World ◽  
New Ideas ◽  
Causes Of Deaths

Respiratory diseases are top-ranked causes of deaths and disabilities around the world, making new approaches to the treatment necessary. In recent years, lung-on-a-chip platforms have emerged as a potential candidate to replace animal experiments because they can successfully simulate human physiology. In this review, we discuss the main respiratory diseases and their pathophysiology, how to model a lung microenvironment, and how to translate it to clinical applications. Furthermore, we propose a novel alveolus lung-on-a-chip platform, based on all currently available methodologies. This review provides solutions and new ideas to improve the alveolar lung-on-a-chip platform. Finally, we provided evidence that approaches such as 3D printing, organ-a-chip devices and organoids can be used in combination, and some challenges could be overcome.

scholarly journals The Clinical Application of 3D-Printed Boluses in Superficial Tumor Radiotherapy

2021 ◽  
Vol 11 ◽  
Author(s):  
Xiran Wang ◽  
Xuetao Wang ◽  
Zhongzheng Xiang ◽  
Yuanyuan Zeng ◽  
Fang Liu ◽  
...  
Keyword(s):  
3D Printing ◽  
Radiation Dose ◽  
Material Selection ◽  
Skin Surface ◽  
High Energy ◽  
Clinical Applications ◽  
Physical Models ◽  
Target Area ◽  
Air Gaps ◽  
3D Printed

During the procedure of radiotherapy for superficial tumors, the key to treatment is to ensure that the skin surface receives an adequate radiation dose. However, due to the presence of the built-up effect of high-energy rays, equivalent tissue compensators (boluses) with appropriate thickness should be placed on the skin surface to increase the target radiation dose. Traditional boluses do not usually fit the skin perfectly. Wet gauze is variable in thickness day to day which results in air gaps between the skin and the bolus. These unwanted but avoidable air gaps lead to a decrease of the radiation dose in the target area and can have a poor effect on the outcome. Three-dimensional (3D) printing, a new rising technology named “additive manufacturing” (AM), could create physical models with specific shapes from digital information by using special materials. It has been favored in many fields because of its advantages, including less waste, low-cost, and individualized design. It is not an exception in the field of radiotherapy, personalized boluses made through 3D printing technology also make up for a number of shortcomings of the traditional commercial bolus. Therefore, an increasing number of researchers have tried to use 3D-printed boluses for clinical applications rather than commercial boluses. Here, we review the 3D-printed bolus’s material selection and production process, its clinical applications, and potential radioactive dermatitis. Finally, we discuss some of the challenges that still need to be addressed with the 3D-printed boluses.

scholarly journals Applications of 3D Bioprinting in Tissue Engineering and Regenerative Medicine

2021 ◽  
Vol 10 (21) ◽  
pp. 4966
Author(s):  
Gia Saini ◽  
Nicole Segaran ◽  
Joseph L. Mayer ◽  
Aman Saini ◽  
Hassan Albadawi ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
3D Printing ◽  
Regenerative Medicine ◽  
Living Cells ◽  
Clinical Applications ◽  
3D Bioprinting ◽  
Future Directions ◽  
Specialized Tissue ◽  
Tissue Models ◽  
Functional Components

Regenerative medicine is an emerging field that centers on the restoration and regeneration of functional components of damaged tissue. Tissue engineering is an application of regenerative medicine and seeks to create functional tissue components and whole organs. Using 3D printing technologies, native tissue mimics can be created utilizing biomaterials and living cells. Recently, regenerative medicine has begun to employ 3D bioprinting methods to create highly specialized tissue models to improve upon conventional tissue engineering methods. Here, we review the use of 3D bioprinting in the advancement of tissue engineering by describing the process of 3D bioprinting and its advantages over other tissue engineering methods. Materials and techniques in bioprinting are also reviewed, in addition to future clinical applications, challenges, and future directions of the field.

Clinical Applications of 3D Printing

Spine ◽  
2017 ◽  
Vol 42 ◽  
pp. S30-S31 ◽  
Author(s):  
Paul A. Anderson
Keyword(s):  
3D Printing ◽  
Clinical Applications

Evaluation of Structural and Biomechanical Characterization of Implant for Cranial Restoration

2019 ◽  
Vol 9 (7) ◽  
pp. 898-903
Author(s):  
Fu-Hui Tsai ◽  
Han-Yi Cheng
Keyword(s):  
Finite Element ◽  
3D Printing ◽  
3D Model ◽  
Three Dimensional ◽  
Biomechanical Properties ◽  
Clinical Applications ◽  
Finite Element Models ◽  
Critical Factors ◽  
Circular Structure

The objective this research was to investigate the biomechanical properties of various structures and thicknesses of implants for cranial restoration. A three-dimensional (3D) printing (3DP) technique has been applied in factories for several decades, but it was only recently introduced to the dental field less than 10 years ago. The structures of pre-shaped cranial mesh implants are critical factors for clinical applications. Many previous studies used finite element models to investigate for implants, but few examined a 3D model for pre-shaped cranial mesh implants with different structures and thicknesses. 3D cranial models were reconstructed using computer tomography to simulate preshaped cranial mesh implants under physical impacts. Data indicated that the stress significantly decreased when implants with greater thicknesses were used. Moreover, the implant with a circular structure created a relatively smaller stress that was approximately 7% lower compared to the implant with a triangular structure. As described above, the results of the present study demonstrate that 3DP-Ti is a reliable material of implants for cranial restoration.

scholarly journals 3D printing: clinical applications in orthopaedics and traumatology

2016 ◽  
Vol 1 (5) ◽  
pp. 121-127 ◽  
Author(s):  
Ferdinando Auricchio ◽  
Stefania Marconi
Keyword(s):  
3D Printing ◽  
Clinical Applications

scholarly journals 3D printed mesh reinforcements enhance the mechanical properties of electrospun scaffolds

2019 ◽  
Vol 23 (1) ◽  
Author(s):  
Nicholas W. Pensa ◽  
Andrew S. Curry ◽  
Paul P. Bonvallet ◽  
Nathan F. Bellis ◽  
Kayla M. Rettig ◽  
...  
Keyword(s):  
Mechanical Properties ◽  
Extracellular Matrix ◽  
3D Printing ◽  
Mechanical Strength ◽  
Bone Graft ◽  
Clinical Applications ◽  
Foreign Body Response ◽  
Poly Lactic Acid ◽  
Electrospun Scaffolds ◽  
3D Printed

Abstract Background There is substantial interest in electrospun scaffolds as substrates for tissue regeneration and repair due to their fibrous, extracellular matrix-like composition with interconnected porosity, cost-effective production, and scalability. However, a common limitation of these scaffolds is their inherently low mechanical strength and stiffness, restricting their use in some clinical applications. In this study we developed a novel technique for 3D printing a mesh reinforcement on electrospun scaffolds to improve their mechanical properties. Methods A poly (lactic acid) (PLA) mesh was 3D-printed directly onto electrospun scaffolds composed of a 40:60 ratio of poly(ε-caprolactone) (PCL) to gelatin, respectively. PLA grids were printed onto the electrospun scaffolds with either a 6 mm or 8 mm distance between the struts. Scanning electron microscopy was utilized to determine if the 3D printing process affected the archtitecture of the electrospun scaffold. Tensile testing was used to ascertain mechanical properties (strength, modulus, failure stress, ductility) of both unmodified and reinforced electrospun scaffolds. An in vivo bone graft model was used to assess biocompatibility. Specifically, reinforced scaffolds were used as a membrane cover for bone graft particles implanted into rat calvarial defects, and implant sites were examined histologically. Results We determined that the tensile strength and elastic modulus were markedly increased, and ductility reduced, by the addition of the PLA meshes to the electrospun scaffolds. Furthermore, the scaffolds maintained their matrix-like structure after being reinforced with the 3D printed PLA. There was no indication at the graft/tissue interface that the reinforced electrospun scaffolds elicited an immune or foreign body response upon implantation into rat cranial defects. Conclusion 3D-printed mesh reinforcements offer a new tool for enhancing the mechanical strength of electrospun scaffolds while preserving the advantageous extracellular matrix-like architecture. The modification of electrospun scaffolds with 3D-printed reinforcements is expected to expand the range of clinical applications for which electrospun materials may be suitable.

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