Biomaterials & Biodevices
Sahariya Priya; Sakar Mohan; Adhigan Murali; R. Ramesh; Sung Soo Han
Abstract
3D-bioprinting is a new technology for creating precise computer-aided design and shape of any human organs, which has the potential to expedite wound coverage and closure. However, the development of complex tissues and organs in 3D printing is till at an infant stage, primarily due to several hurdles, ...
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3D-bioprinting is a new technology for creating precise computer-aided design and shape of any human organs, which has the potential to expedite wound coverage and closure. However, the development of complex tissues and organs in 3D printing is till at an infant stage, primarily due to several hurdles, such as optimization, biomechanical stability, and printing resolution. Collagen is natural polymer, which found abundantly in the extracellular matrix (ECM) and exhibit excellent biological properties. These collagen-based bio-inks can be tailored for different purposes, including wound healing, tissue engineering, organ transplantation and drug delivery systems. Until now, thermoplastic collagen/collagen bio-inks are limited to use in additive manufacturing (AM). The adaptation of thermoplastic collagen/ collagen bio-inks in AM techniques is therefore a great concern. The use of thermoplastic collagen and collagen-based bio-ink/powder in additive manufacturing can open up new applications in biomedical industries. In this context, this review summarizes the development of 3D bio-printing, its potential biomedical applications, and current challenges in the field.
Adhigan Murali; Saravanan Ashok Vallal; Mohan Sakar; R. Ramesh; M. Devendiran; N. Suthanthira Vanitha
Abstract
It is not an exaggerated fact that the whole world relies on the energy storage systems such as Li-ion batteries (LIBs). Li-ion batteries have been widely used in electric vehicles and electronic devices such as laptops, mobile phones, etc. However, the commercial Li-ion batteries have many issues associated ...
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It is not an exaggerated fact that the whole world relies on the energy storage systems such as Li-ion batteries (LIBs). Li-ion batteries have been widely used in electric vehicles and electronic devices such as laptops, mobile phones, etc. However, the commercial Li-ion batteries have many issues associated with safety and durability including the thermal runaway and the use of toxic solvents during the construction of batteries. In order to highlight the recent developments towards addressing these issues, we have summarized the major impact in replacing the toxic solvents, which are conventionally used to dissolve the binder in the commercial Li-ion batteries, with the aqueous-based binder called green binders. Further, an emphasis has been given on the importance of shifting from flammable liquid electrolytes to non-flammable solid-electrolytes, which essentially suppress the issues such as leakage problems, mechanical failure and fire explosives in LIBs. Even though considerable works have been performed on the development of green-based solid polymer electrolytes, it still needs more effort to overcome the obstacles towards improving the properties of the solid-polymer matrix, which is their low ionic conductivity at low temperatures. Further research in this direction has been highlighted in this review, which involves improving the interfacial contacts in the solid-polymer electrolytes, where the interfacial interaction and conductive mechanisms are yet to be clearly investigated to have the solid-electrolytes with improved electrochemical property.
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