Structure, Properties, and In Vitro Behavior of Heat-Treated Calcium Sulfate Scaffolds Fabricated by 3D Printing

Asadi‐Eydivand, Mitra; Solati‐Hashjin, Mehran; Shafiei, Seyedeh Sara; Mohammadi, Sepideh; Hafezi, Masoud; Osman, Noor Azuan Abu

doi:10.1371/journal.pone.0151216

Cited by 58 publications

(23 citation statements)

References 60 publications

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“…[61,174,249,[280][281][282][283] However, the fatigue strength of 3D printed objects is usually unsatisfactory due to the porosity and surface roughness of the printed structures, which necessitates the complex and expensive postmanufacturing treatments, e.g., hot isostatic pressing (HIP) and heat treatments, for improving the mechanical strength of 3D printed objects. [249,255,284,285] Moreover, the soft mechanical nature of polymers and biomaterials limits their printability in 3D structures. [61,255,283,286,287] Recent research shows that fiber reinforcement is an effective approach for improving the mechanical properties of the polymers and biomaterials in 3D printing.…”

Section: D Printingmentioning

confidence: 99%

Bio‐Derived Natural Materials Based Triboelectric Devices for Self‐Powered Ubiquitous Wearable and Implantable Intelligent Devices

Yang

Fan

2020

Advanced Sustainable Systems

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The capability of devices in future ubiquitous networked wearable and implantable electronics to efficiently scavenge and store operational power from their working environment through sustainable pathways would enable viable self‐powering schemes in societally‐pervasive applications such as advanced healthcare and robotics. Triboelectric nanogenerators (TENGs) can efficiently harvest the ubiquitous mechanical energy for powering electronics and sensors. However, the majority of demonstrated TENG prototypes have been built with materials that are not biodegradable or biocompatible, which significantly hinders the application of TENGs for wearable and implantable technologies. In this review, the recent progress of the wearable and implantable triboelectric devices built with bio‐derived natural materials is summarized. The properties of these natural biopolymers are discussed in the context of self‐powered triboelectric applications. The common manufacturing methods for processing these materials into triboelectric devices are also discussed. In addition, the applications of the bio‐derived natural materials based TENGs for in vitro and in vivo applications are discussed. Finally, the outstanding challenges and potential opportunities for the development of bio‐derived natural materials based triboelectric devices targeting wearable and implantable human‐integrated applications are analyzed.

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Section: D Printingmentioning

confidence: 99%

Bio‐Derived Natural Materials Based Triboelectric Devices for Self‐Powered Ubiquitous Wearable and Implantable Intelligent Devices

Yang

Fan

2020

Advanced Sustainable Systems

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“…Apart from the chemical properties, pore size, and volume, along with mechanical properties, scaffold design and fabrication methods are the parameters defining the scaffold efficiency, which are reviewed below. 84,85 Liver scaffolds can be fabricated with a wide range of materials, mostly naturally derived or synthetic polymers, due to their intrinsic characteristics. Although employing polymeric materials and fabricating them using engineering methods have a lack of inherent vascular network, attempts have been conducted to retrain the liver network and structure through novel methods and materials.…”

Section: Extracellular Matrixmentioning

confidence: 99%

Liver Tissue Engineering as an Emerging Alternative for Liver Disease Treatment

Mirdamadi

Kalhori

Zakeri

et al. 2020

Tissue Engineering Part B: Reviews

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Chronic liver diseases affect thousands of lives throughout the world every year. The shortage of liver donors for transplantation has been the main driving force to employ alternative methods such as liver tissue engineering (LTE) in fabricating a three-dimensional transplantable liver tissue or enhancing cell delivery techniques alleviating the need for liver donors. LTE consists of three components, cells, ECM (extracellular matrix), and signaling molecules, which we discuss the first and second. The three most common cell sources used in LTE are human and animal primary hepatocytes, and stem cells for different applications. Two major categories of ECM are used to mimic the microenvironment of these cells, named scaffolds and microbeads. Scaffolds have been made by numerous methods with a wide range of synthetic and natural biomaterials. Cell encapsulation has also been utilized by many polymeric biomaterials. To investigate their functions, many properties have been discussed in the literature, such as biochemical, geometrical, and mechanical properties, in both of these categories. Overall, LTE shows excellent potential in assisting hepatic disorders. However, some challenges exist that prevent the practical use of it clinically, making LTE an ongoing research subject in the scientific society.

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“…6 Stabilization of synthetic powders necessitates the use of binder chemicals which leave toxic UTILITY OF ECM POWDERS IN TISSUE ENGINEERING and acidic residues in the printed construct. 3,54 Bio-ink, however, can be solidified using non-toxic methods.…”

Section: D Printing (3dp)mentioning

confidence: 99%

Utility of extracellular matrix powders in tissue engineering

et al. 2018

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Extracellular matrix (ECM) materials have had remarkable success as scaffolds in tissue engineering (TE) and as therapies for tissue injury whereby the ECM microenvironment promotes constructive remodeling and tissue regeneration. ECM powder and solubilized derivatives thereof have novel applications in TE and RM afforded by the capacity of these constructs to be dynamically modulated. The powder form allows for effective incorporation and penetration of reagents; hence, ECM powder is an efficacious platform for 3D cell culture and vehicle for small molecule delivery. ECM powder offers minimally invasive therapy for tissue injury and successfully treatment for wounds refractory to first-line therapies. Comminution of ECM and fabrication of powder-derived constructs, however, may compromise the biological integrity of the ECM. The current lack of optimized fabrication protocols prevents a more extensive and effective clinical application of ECM powders. Further study on methods of ECM powder fabrication and modification is needed.

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Structure, Properties, and In Vitro Behavior of Heat-Treated Calcium Sulfate Scaffolds Fabricated by 3D Printing

Cited by 58 publications

References 60 publications

Bio‐Derived Natural Materials Based Triboelectric Devices for Self‐Powered Ubiquitous Wearable and Implantable Intelligent Devices

Bio‐Derived Natural Materials Based Triboelectric Devices for Self‐Powered Ubiquitous Wearable and Implantable Intelligent Devices

Liver Tissue Engineering as an Emerging Alternative for Liver Disease Treatment

Utility of extracellular matrix powders in tissue engineering

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