Polymeric biomaterials based on polylactide, chitosan and hydrogels in medicine
Само за регистроване кориснике
2017
Поглавље у монографији (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
Polymeric biomaterials represent large and very adaptable class of biomaterials, which makes them very suitable for diversity of biomedical applications. Polymers can be synthesized to have a variety of structures and suitable chemical, physical, biomimetic and surface properties. An overabundance of polymeric biomaterials with different compositions and physicochemical properties have already been developed and investigated; however, there are still many active studies about these materials. This chapter ensures a structural review of biodegradable polymers and discusses their physicochemical characteristics, structure property, applications and limitations in medicine. It is the authors' intent to provide an insight over the available synthetic and natural polymer classes. Some types of polymer materials are less discussed than the other more relevant. A biocompatible, degradable polymer, polylactic acid is very popular so called green 'eco-friendly' material with a most promising de...velopment prospect. Besides biocompatibility and biodegradability, natural polymer, chitosan, possess outstanding properties. Hydrogels are super absorbent polymeric materials with one of the main role in health care. For these biopolymers, reviews are referenced to present guidance for further reading.
Кључне речи:
Polymeric biomaterials / Polylactic acid / Hydrogels / ChitosanИзвор:
Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices, 2017, 119-147Издавач:
- Springer International Publishing
Институција/група
Inovacioni centarTY - CHAP AU - Mitrović, A. AU - Munćan, Jelena S. AU - Hut, Igor AU - Pelemiš, Svetlana AU - Čolić, Katarina AU - Matija, Lidija PY - 2017 UR - https://machinery.mas.bg.ac.rs/handle/123456789/2686 AB - Polymeric biomaterials represent large and very adaptable class of biomaterials, which makes them very suitable for diversity of biomedical applications. Polymers can be synthesized to have a variety of structures and suitable chemical, physical, biomimetic and surface properties. An overabundance of polymeric biomaterials with different compositions and physicochemical properties have already been developed and investigated; however, there are still many active studies about these materials. This chapter ensures a structural review of biodegradable polymers and discusses their physicochemical characteristics, structure property, applications and limitations in medicine. It is the authors' intent to provide an insight over the available synthetic and natural polymer classes. Some types of polymer materials are less discussed than the other more relevant. A biocompatible, degradable polymer, polylactic acid is very popular so called green 'eco-friendly' material with a most promising development prospect. Besides biocompatibility and biodegradability, natural polymer, chitosan, possess outstanding properties. Hydrogels are super absorbent polymeric materials with one of the main role in health care. For these biopolymers, reviews are referenced to present guidance for further reading. PB - Springer International Publishing T2 - Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices T1 - Polymeric biomaterials based on polylactide, chitosan and hydrogels in medicine EP - 147 SP - 119 DO - 10.1007/978-3-319-68025-5_5 ER -
@inbook{ author = "Mitrović, A. and Munćan, Jelena S. and Hut, Igor and Pelemiš, Svetlana and Čolić, Katarina and Matija, Lidija", year = "2017", abstract = "Polymeric biomaterials represent large and very adaptable class of biomaterials, which makes them very suitable for diversity of biomedical applications. Polymers can be synthesized to have a variety of structures and suitable chemical, physical, biomimetic and surface properties. An overabundance of polymeric biomaterials with different compositions and physicochemical properties have already been developed and investigated; however, there are still many active studies about these materials. This chapter ensures a structural review of biodegradable polymers and discusses their physicochemical characteristics, structure property, applications and limitations in medicine. It is the authors' intent to provide an insight over the available synthetic and natural polymer classes. Some types of polymer materials are less discussed than the other more relevant. A biocompatible, degradable polymer, polylactic acid is very popular so called green 'eco-friendly' material with a most promising development prospect. Besides biocompatibility and biodegradability, natural polymer, chitosan, possess outstanding properties. Hydrogels are super absorbent polymeric materials with one of the main role in health care. For these biopolymers, reviews are referenced to present guidance for further reading.", publisher = "Springer International Publishing", journal = "Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices", booktitle = "Polymeric biomaterials based on polylactide, chitosan and hydrogels in medicine", pages = "147-119", doi = "10.1007/978-3-319-68025-5_5" }
Mitrović, A., Munćan, J. S., Hut, I., Pelemiš, S., Čolić, K.,& Matija, L.. (2017). Polymeric biomaterials based on polylactide, chitosan and hydrogels in medicine. in Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices Springer International Publishing., 119-147. https://doi.org/10.1007/978-3-319-68025-5_5
Mitrović A, Munćan JS, Hut I, Pelemiš S, Čolić K, Matija L. Polymeric biomaterials based on polylactide, chitosan and hydrogels in medicine. in Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices. 2017;:119-147. doi:10.1007/978-3-319-68025-5_5 .
Mitrović, A., Munćan, Jelena S., Hut, Igor, Pelemiš, Svetlana, Čolić, Katarina, Matija, Lidija, "Polymeric biomaterials based on polylactide, chitosan and hydrogels in medicine" in Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices (2017):119-147, https://doi.org/10.1007/978-3-319-68025-5_5 . .