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Published in:
Effects of Radiation on the Environment Read chapter Read first chapter

2019 | OriginalPaper | Chapter

Plasma Irradiation of Polymers: Surface to Biological Mitigation

Authors : Narendra Kumar Agrawal, Neha Sharma, Tamanna Kumari Sharma, Priti Agarwal, Ravi Agarwal

Published in: Radiation Effects in Polymeric Materials

Publisher: Springer International Publishing

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Abstract

Development in science and technology has made human life much simpler, but evolution and progress of time as well as increasing human demand have generated problems related to energy, health [1], etc. Progress in science and technology is trying to solve these issues to make the human life more comfortable. Growing requirement of biomedical devices, replacement of body parts after their failure, body implants [2, 3], bio-separation, sterilizations [4, 5], biosensors, etc. [6, 7], have shown need of development of advance smart materials (biomaterials). The choice of any material to be used as biomaterial/biomedical applications [8] depends on physical, chemical, surface, and biological properties, i.e., the presence of functional groups, surface free energy, hydrophilicity, surface morphology affects use of any material as biomaterial [9]. In other words, materials having high bio-adoptability and biocompatibility can only be used as biomaterials [10, 11]. Polymers arise as a suitable alternative of conventional biomaterial from last few decades, for synthesis of important biomaterials in modern manufacturing processes as they offer wide varieties of physical, chemical, biological, mechanical, and elastic properties with good processability. None of the normally available polymers possess surface and chemical properties required for many of biomedical applications. Nanomaterials and low-temperature plasma processing offer a novel route for surface and chemical modification in controlled manner without affecting their bulk properties [12]. Plasama processing can be utilized in various pathways to control the desired properties of modified materials, makes plasma so important that we can say “Plasma will future: Plasma for mankind.” Present work shows efficient and relevant route for synthesis of nanobiomaterials using nanotechnology and plasma processing to fabricate biomedical devices for biomedical applications [13].

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previous chapter Effects of Radiations on the Properties of Polycarbonate
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Metadata
Title
Plasma Irradiation of Polymers: Surface to Biological Mitigation
Authors
Narendra Kumar Agrawal
Neha Sharma
Tamanna Kumari Sharma
Priti Agarwal
Ravi Agarwal
Copyright Year
2019
Book
Radiation Effects in Polymeric Materials

Print ISBN: 978-3-030-05769-5

Electronic ISBN: 978-3-030-05770-1

Copyright Year: 2019

DOI
https://doi.org/10.1007/978-3-030-05770-1_10

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