4D printing: a cutting-edge platform for biomedical applications

Naniz, Moqaddaseh Afzali; Askari, Mohsen; Zolfagharian, Ali; Naniz, Mehrdad Afzali; Bodaghi, Mahdi

doi:10.1088/1748-605x/ac8e42

Cited by 28 publications

(17 citation statements)

References 209 publications

(227 reference statements)

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“…In case of tissue regeneration, for example, functional scaffolds purposely engineered to assist in remodeling and replacing diseased or injured areas represent an ongoing topic of research. In this respect, new materials showing bio-mimicking features and bio-responsiveness can greatly help the development of such technologies (Free, 2021;Naniza et al, 2022;Senatov et al, 2016;Tamay et al, 2019;Zhang et al, 2018).…”

Section: Insights On 4dp In the Biomedical Fieldmentioning

confidence: 99%

Towards 4D printing in pharmaceutics

Gazzaniga

Foppoli

Cerea

et al. 2023

International Journal of Pharmaceutics: X

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Section: Insights On 4dp In the Biomedical Fieldmentioning

confidence: 99%

Towards 4D printing in pharmaceutics

Gazzaniga

Foppoli

Cerea

et al. 2023

International Journal of Pharmaceutics: X

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“…The integration of molecularly imprinted materials responding to internal (e.g., cell-secreted protein degradable hydrogels) and external stimuli (e.g., temperature, electric and magnetic fields, light-responsive systems) in 3D CAD-AM scaffolds may open new avenues to control the presentation of biomolecular signals following a cell-demanding mechanism, and to recapitulate the cell/ECM dual reciprocity interaction [ 70 ]. Loading magnetically responsive particles within scaffolds was used to trigger the release of biomolecules, such as GFs, to stimulate cells proliferation and differentiation without affecting matrix degradation [ 71 , 72 ].…”

Section: Current Advances Of Synthetic Ecm-mimicking Scaffoldsmentioning

confidence: 99%

Review on Bioinspired Design of ECM-Mimicking Scaffolds by Computer-Aided Assembly of Cell-Free and Cell Laden Micro-Modules

Salerno

Netti

2023

JFB

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Tissue engineering needs bioactive drug delivery scaffolds capable of guiding cell biosynthesis and tissue morphogenesis in three dimensions. Several strategies have been developed to design and fabricate ECM-mimicking scaffolds suitable for directing in vitro cell/scaffold interaction, and controlling tissue morphogenesis in vivo. Among these strategies, emerging computer aided design and manufacturing processes, such as modular tissue unit patterning, promise to provide unprecedented control over the generation of biologically and biomechanically competent tissue analogues. This review discusses recent studies and highlights the role of scaffold microstructural properties and their drug release capability in cell fate control and tissue morphogenesis. Furthermore, the work highlights recent advances in the bottom-up fabrication of porous scaffolds and hybrid constructs through the computer-aided assembly of cell-free and/or cell-laden micro-modules. The advantages, current limitations, and future challenges of these strategies are described and discussed.

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“…In more detail, samples having different original shapes, endowed with such spatial encumbrance as to avoid rapid emptying through the sphincters of the selected organs, were produced by HME and FDM. In this respect, modifications occurring on a 3D material configuration over time, triggered by an external stimulus of a non-mechanical nature and resulting in macroscopic shape changes, has been associated with the concept of 4D printing, in which time represented the fourth dimension [ 15 , 42 , 43 , 44 ]. Indeed, the resulting PVA-based prototypes turned out able to take on, after production, a temporary collapsed shape and to quickly recover the original one in the desired environment.…”

Section: Introductionmentioning

confidence: 99%

Insights into the Safety and Versatility of 4D Printed Intravesical Drug Delivery Systems

et al. 2023

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This paper focuses on recent advancements in the development of 4D printed drug delivery systems (DDSs) for the intravesical administration of drugs. By coupling the effectiveness of local treatments with major compliance and long-lasting performance, they would represent a promising innovation for the current treatment of bladder pathologies. Being based on a shape-memory pharmaceutical-grade polyvinyl alcohol (PVA), these DDSs are manufactured in a bulky shape, can be programmed to take on a collapsed one suitable for insertion into a catheter and re-expand inside the target organ, following exposure to biological fluids at body temperature, while releasing their content. The biocompatibility of prototypes made of PVAs of different molecular weight, either uncoated or coated with Eudragit®-based formulations, was assessed by excluding relevant in vitro toxicity and inflammatory response using bladder cancer and human monocytic cell lines. Moreover, the feasibility of a novel configuration was preliminarily investigated, targeting the development of prototypes provided with inner reservoirs to be filled with different drug-containing formulations. Samples entailing two cavities, filled during the printing process, were successfully fabricated and showed, in simulated urine at body temperature, potential for controlled release, while maintaining the ability to recover about 70% of their original shape within 3 min.

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4D printing: a cutting-edge platform for biomedical applications

Cited by 28 publications

References 209 publications

Towards 4D printing in pharmaceutics

Towards 4D printing in pharmaceutics

Review on Bioinspired Design of ECM-Mimicking Scaffolds by Computer-Aided Assembly of Cell-Free and Cell Laden Micro-Modules

Insights into the Safety and Versatility of 4D Printed Intravesical Drug Delivery Systems

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