3D printing of PLGA scaffolds for tissue engineering

Миронов, А. Н.; Grigoryev, A. M.; Кротова, Л. И.; Skaletsky, Nikolaj N.; Попов, В. К.; Sevastianov, V. I.

doi:10.1002/jbm.a.35871

Cited by 58 publications

(36 citation statements)

References 14 publications

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“…They do not display toxic side effects when being used in the pharmaceuticals and biological materials, with the exception of lactose deficiency. PLGAs are extremely thermolabile compounds When being processed at a heightened temperature, they may provoke the formation of toxic components and structural cross‐linking which in turn causes their unpredictable behavior in the recipient's body …”

Section: Biomaterials For Dental 3d Printingmentioning

confidence: 99%

3D Printing and Digital Processing Techniques in Dentistry: A Review of Literature

et al. 2019

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In recent years, the rapid development of 3D printing technologies lead to its new applications in the area of healthcare and medicine, including dentistry, orthopedics, cardiovascular, pharmaceutics, neurosurgery, engineered tissue models, medical devices, and anatomical models. Dentistry is widely acknowledged to benefit from 3D printing technologies due to its needs for the customization and personalization of dental products. In this review, the authors discuss and summarize various 3D imaging technologies and the recent advances of 3D digital processing techniques in dentistry in an effort to give a new perspective and greater understanding of the current development of 3D printing technologies in dentistry. It is anticipated that this review will explore why 3D printing is important to dentistry, and why dentistry motivates development in 3D printing applications. Further, current challenges and further perspectives are also discussed which helps researchers to optimize the 3D printing technology in dentistry, improve 3D printing strategies, and direct future dental bioprinting and translational applications.

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Section: Biomaterials For Dental 3d Printingmentioning

confidence: 99%

3D Printing and Digital Processing Techniques in Dentistry: A Review of Literature

et al. 2019

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“…3D printing is as ground-breaking fabrication process o®ering innovative solutions in variety of¯elds including tissue engineering, 172,173 cancer therapy 174 and generation of arti¯cial organ. 175 3D printing combined with advanced techniques of material design and fabrication is even capable to fabricate materials for arti¯cial sca®olds for bone reconstruction and regeneration.…”

Section: Bp For 3d Printing Sca®oldsmentioning

confidence: 99%

Black phosphorus as a versatile nanoplatform: From unique properties to biomedical applications

Xiong

Chen

Liu

et al. 2020

J. Innov. Opt. Health Sci.

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Black phosphorus (BP) or phosphorene, a new superstar among two-dimensional (2D) materials, has sparked huge scientific interest since its discovery in 2014. BP offers unique characteristics including high drug loading efficiency, excellent photodynamic and photothermal properties and good biocompatibility. These characteristics expand versatility of BP in nanomedicine. Although the outlook of BP seems promising, its practical biomedical applications are still at the very initial stage especially in comparison to other thoroughly investigated inorganic nanomaterials. This paper reviews BP structure and properties as well as its preparation approaches with the emphasis on techniques to improve BP stability and biocompatibility for their further usage in physiological environment. Meanwhile, recent progress made in various biomedical research fields from bioimaging to biosensing is discussed. Last, but not least, current challenges and prospects for BP in biomedicine are briefly examined, which will be useful to guide future developments of BP.

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“…Recently, biocompatible PLGA scaffolds have been produced using 3D printing for use in tissue engineering [106]. Electrospun PLGA-based hybrid nano-fibrous membranes and scaffolds have been widely used for skin, bone, nerve, and soft tissue engineering applications [105].…”

Section: Polylactic-co-glycolic Acidmentioning

confidence: 99%

Polymeric Scaffolds for Pancreatic Tissue Engineering: A Review

2017

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In recent years, there has been an alarming increase in the incidence of diabetes, with one in every eleven individuals worldwide suffering from this debilitating disease. As the available treatment options fail to reduce disease progression, novel avenues such as the bioartificial pancreas are being given serious consideration. In the past decade, the research focus has shifted towards the field of tissue engineering, which helps to design biological substitutes for repair and replacement of non-functional or damaged organs. Scaffolds constitute an integral part of tissue engineering; they have been shown to mimic the native extracellular matrix, thereby supporting cell viability and proliferation. This review offers a novel compilation of the recent advances in polymeric scaffolds, which are used for pancreatic tissue engineering. Furthermore, in this article, the design strategies for bioartificial pancreatic constructs and their future applications in cell-based therapy are discussed.

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3D printing of PLGA scaffolds for tissue engineering

Cited by 58 publications

References 14 publications

3D Printing and Digital Processing Techniques in Dentistry: A Review of Literature

3D Printing and Digital Processing Techniques in Dentistry: A Review of Literature

Black phosphorus as a versatile nanoplatform: From unique properties to biomedical applications

Polymeric Scaffolds for Pancreatic Tissue Engineering: A Review

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